High quality factor interconnect for rf circuits

ABSTRACT

Embodiments of radio frequency (RF) devices are disclosed having interconnection paths with capacitive structures having improved quality (Q) factors. In one embodiment, an RF device includes an inductor having an inductor terminal and a semiconductor die. The semiconductor die includes one or more active semiconductor devices that include a device contact. The device contact provided by the one or more active semiconductor devices is positioned so as to be vertically aligned directly below the inductor terminal. The inductor terminal and the device contact are electrically connected with an interconnection path that includes a capacitive structure. To prevent or reduce current crowding, the interconnection path is vertically aligned so as to extend directly between the inductor terminal and the device contact. In this manner, the interconnection path electrically connects the inductor terminal and the device contact without degrading the Q factor of the RF device.

RELATED APPLICATIONS

The present application claims priority to U.S. Provisional Patent Application No. 61/831,666, filed Jun. 6, 2013; U.S. Provisional Patent Application No. 61/860,932, filed Aug. 1, 2013; U.S. Provisional Patent Application No. 61/909,028, filed Nov. 26, 2013; U.S. Provisional Patent Application No. 61/938,884, filed Feb. 12, 2014; U.S. Provisional Patent Application No. 61/949,581, filed Mar. 7, 2014; U.S. Provisional Patent Application No. 61/951,844, filed Mar. 12, 2014; U.S. Provisional Patent Application No. 61/982,946, filed Apr. 23, 2014; U.S. Provisional Patent Application No. 61/982,952, filed Apr. 23, 2014; U.S. Provisional Patent Application No. 61/982,971, filed Apr. 23, 2014; and U.S. Provisional Patent Application No. 62/008,192, filed Jun. 5, 2014.

The present application is related to concurrently filed U.S. patent application Ser. No. ______, entitled “TUNABLE RF FILTER STRUCTURE FORMED BY A MATRIX OF WEAKLY COUPLED RESONATORS;” concurrently filed U.S. patent application Ser. No. ______, entitled “TUNABLE RF FILTER PATHS FOR TUNABLE RF FILTER STRUCTURES;” concurrently filed U.S. patent application Ser. No. ______, entitled “NONLINEAR CAPACITANCE LINEARIZATION;” concurrently filed U.S. patent application Ser. No. ______, entitled “TUNABLE RF FILTER BASED RF COMMUNICATIONS SYSTEM;” and concurrently filed U.S. patent application Ser. No. ______, entitled “MULTI-BAND INTERFERENCE OPTIMIZATION.”

All of the applications listed above are hereby incorporated herein by reference in their entireties.

FIELD OF THE DISCLOSURE

Embodiments of the present disclosure relate to radio frequency (RF) communications systems, which may include RF front-end circuitry, RF transceiver circuitry, RF amplifiers, direct current (DC)-DC converters, RF filters, RF antennas, RF switches, RF combiners, RF splitters, the like, or any combination thereof.

BACKGROUND

As wireless communications technologies evolve, wireless communications systems become increasingly sophisticated. As such, wireless communications protocols continue to expand and change to take advantage of the technological evolution. As a result, to maximize flexibility, many wireless communications devices must be capable of supporting any number of wireless communications protocols, each of which may have certain performance requirements, such as specific out-of-band emissions requirements, linearity requirements, or the like. Further, portable wireless communications devices are typically battery powered and need to be relatively small, and have low cost. As such, to minimize size, cost, and power consumption, RF circuitry in such a device needs to be as simple, small, flexible, and efficient as is practical. Thus, there is a need for RF circuitry in a communications device that is low cost, small, simple, flexible, and efficient.

SUMMARY

Embodiments of radio frequency (RF) devices are disclosed having interconnection paths with capacitive structures having improved quality (Q) factors. In one embodiment, an RF device includes an inductor having an inductor terminal and a semiconductor die. The semiconductor die includes one or more active semiconductor devices that include a device contact. The device contact provided by the one or more active semiconductor devices is positioned so as to be vertically aligned directly below the inductor terminal. The inductor terminal and the device contact are electrically connected with an interconnection path that includes a capacitive structure. To prevent or reduce current crowding, the interconnection path is vertically aligned so as to extend directly between the inductor terminal and the device contact. In this manner, the interconnection path electrically connects the inductor terminal and the device contact without degrading the Q factor of the RF device.

Those skilled in the art will appreciate the scope of the present disclosure and realize additional aspects thereof after reading the following detailed description of the preferred embodiments in association with the accompanying drawing figures.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings incorporated in and forming a part of this specification illustrate several aspects of the disclosure, and together with the description serve to explain the principles of the disclosure.

FIG. 1 shows traditional communications circuitry according to the prior art.

FIG. 2 shows the traditional communications circuitry according to the prior art.

FIG. 3 shows the traditional communications circuitry according to the prior art.

FIG. 4 shows RF communications circuitry according to one embodiment of the RF communications circuitry.

FIG. 5 is a graph illustrating filtering characteristics of a first tunable RF filter path and a second tunable RF filter path illustrated in FIG. 4 according to one embodiment of the first tunable RF filter path and the second tunable RF filter path.

FIGS. 6A and 6B are graphs illustrating filtering characteristics of the first tunable RF filter path and the second tunable RF filter path, respectively, illustrated in FIG. 4 according to an alternate embodiment of the first tunable RF filter path and the second tunable RF filter path, respectively.

FIG. 7 shows the RF communications circuitry according to one embodiment of the RF communications circuitry.

FIG. 8 shows the RF communications circuitry according to an alternate embodiment of the RF communications circuitry.

FIGS. 9A and 9B are graphs illustrating filtering characteristics of the first tunable RF filter path and the second tunable RF filter path, respectively, illustrated in FIG. 8 according to an additional embodiment of the first tunable RF filter path and the second tunable RF filter path.

FIGS. 10A and 10B are graphs illustrating filtering characteristics of a first traditional RF duplexer and a second traditional RF duplexer, respectively, illustrated in FIG. 3 according to the prior art.

FIG. 11 shows the RF communications circuitry according to one embodiment of the RF communications circuitry.

FIG. 12 shows the RF communications circuitry according to an alternate embodiment of the RF communications circuitry.

FIG. 13 shows the RF communications circuitry according to an additional embodiment of the RF communications circuitry.

FIG. 14 shows the RF communications circuitry according to another embodiment of the RF communications circuitry.

FIG. 15 shows the RF communications circuitry according to a further embodiment of the RF communications circuitry.

FIG. 16 shows the RF communications circuitry according to one embodiment of the RF communications circuitry.

FIG. 17 shows the RF communications circuitry according to an alternate embodiment of the RF communications circuitry.

FIG. 18 shows the RF communications circuitry according to an additional embodiment of the RF communications circuitry.

FIG. 19 shows the RF communications circuitry according to another embodiment of the RF communications circuitry.

FIG. 20 shows the RF communications circuitry according to a further embodiment of the RF communications circuitry.

FIG. 21 illustrates one embodiment of a tunable radio frequency (RF) filter structure that defines multiple tunable RF filtering paths that are independent of each other.

FIG. 22 illustrates one embodiment of a tunable RF filter path shown in FIG. 21 having cross-coupling capacitors arranged in a V-bridge structure.

FIG. 23 illustrates another embodiment of the tunable RF filter path shown in FIG. 21 having cross-coupling capacitors arranged in an X-bridge structure.

FIG. 24 illustrates another embodiment of the tunable RF filter path shown in FIG. 21 having a cross-coupling capacitor arranged in a single positive bridge structure.

FIG. 25 illustrates another embodiment of the tunable RF filter path shown in FIG. 21 having cross-coupling capacitors arranged in an H-bridge structure.

FIG. 26 illustrates another embodiment of the tunable RF filter path shown in FIG. 21 having cross-coupling capacitors arranged in a double H-bridge structure.

FIG. 27 illustrates another embodiment of the tunable RF filter path shown in FIG. 21 having four weakly coupled resonators with magnetic and electric couplings between them.

FIGS. 28A-28D disclose different embodiments of a tunable RF filter structure, each with a different number of input terminals and output terminals.

FIG. 29 illustrates one embodiment of a tunable radio frequency (RF) filter structure having four resonators and cross-coupling capacitive structures electrically connected between the four resonators so as to form a 2×2 matrix with the four resonators. In alternative embodiments, fewer (e.g., three) resonators or more (e.g., five or more) resonators may be provided.

FIG. 30 illustrates another embodiment of a tunable RF filter structure having M number of rows and N number of columns of resonators that are electrically connected by cross-coupling capacitive structures so that the tunable RF filter structure is arranged so as to form an M×N two-dimensional matrix of the resonators.

FIG. 31 illustrates the tunable RF filter structure shown in FIG. 30 electrically connected to various RF antennas.

FIG. 32 illustrates the tunable RF filter structure shown in FIG. 30 with two tunable RF filter paths highlighted for performing Multiple Input Multiple Output (MIMO), Single Input Multiple Output (SIMO), Multiple Input Single Output (MISO), and Single Input Single Output (SISO) operations.

FIG. 33 illustrates another embodiment of a tunable RF filter structure with amplifier stages electrically connected within and between tunable RF filter paths.

FIG. 34 illustrates an embodiment of a tunable RF filter structure integrated into an integrated circuit (IC) package with multiple and separate semiconductor dies.

FIG. 35 illustrates an embodiment of the same tunable RF filter structure shown in FIG. 34, but now integrated into an IC package with a single semiconductor die.

FIG. 36 illustrates one embodiment of a tunable RF filter structure having resonators and cross-coupling capacitive structures electrically connected between the resonators so as to form a three-dimensional matrix of the resonators.

FIG. 37 illustrates an embodiment of a radio frequency (RF) device integrated into an integrated circuit (IC) package, wherein the RF device includes an inductor having inductor terminals electrically connected to device contacts of active semiconductor devices with interconnection paths that may include capacitive structures.

FIG. 38 illustrates another embodiment of the RF device having an inductor terminal electrically connected to a device contact of an active semiconductor device with an interconnection path having a capacitive structure, where the active semiconductor device is grounded to a virtual or a real ground connection.

FIG. 39 illustrates an embodiment of RF devices that are electrically connected with a trace formed from a metallic layer on a package board or alternatively to a thick top metal layer of a Back-End-Of-Line (BEOL).

FIG. 40 illustrates an embodiment of RF devices that are electrically connected with a trace within a BEOL).

FIG. 41 illustrates a top view of an embodiment of an interconnection path having a metal-insulator-metal (MIM) capacitive structure formed within the interconnection path.

FIG. 42 illustrates a top view of an embodiment of an interconnection path having a metal-oxide-metal (MOM) capacitive structure.

FIG. 43 illustrates a top view of an embodiment of an interconnection path having metal-to-metal (MTM) capacitive structures formed by parallel metallic walls formed across drain contacts provided by active semiconductor devices.

FIG. 44 illustrates a top view of an embodiment of an interconnection path having MTM capacitive structures formed by posts surrounded by metallic cages formed across drain contacts provided by active semiconductor devices.

FIG. 45 illustrates another embodiment of an MTM capacitive structure formed using parallel metallic walls formed across a drain contact and a source contact of an active semiconductor device.

FIG. 46 illustrates another embodiment of an MTM capacitive structure formed using parallel metallic walls formed across a drain contact, a source contact, and a gate contact of an active semiconductor device.

DETAILED DESCRIPTION

The embodiments set forth below represent the necessary information to enable those skilled in the art to practice the disclosure and illustrate the best mode of practicing the disclosure. Upon reading the following description in light of the accompanying drawings, those skilled in the art will understand the concepts of the disclosure and will recognize applications of these concepts not particularly addressed herein. It should be understood that these concepts and applications fall within the scope of the disclosure and the accompanying claims.

RF communications circuitry, which includes a first RF filter structure, is disclosed according to a first embodiment of the present disclosure. The first RF filter structure includes a first tunable RF filter path and a second tunable RF filter path. The first tunable RF filter path includes a pair of weakly coupled resonators. Additionally, a first filter parameter of the first tunable RF filter path is tuned based on a first filter control signal. A first filter parameter of the second tunable RF filter path is tuned based on a second filter control signal.

In one embodiment of the first RF filter structure, the first tunable RF filter path is directly coupled between a first common connection node and a first connection node. The second tunable RF filter path is directly coupled between a second connection node and the first common connection node.

In one embodiment of the RF communications system, the first tunable RF filter path and the second tunable RF filter path do not significantly load one another at frequencies of interest. As such, by directly coupling the first tunable RF filter path and the second tunable RF filter path to the first common connection node; front-end RF switching elements may be avoided, thereby reducing cost, size, and non-linearity; and increasing efficiency and flexibility of the RF communications system. In one embodiment of the RF communications system, the first common connection node is coupled to an antenna.

Embodiments of the RF communications system include frequency division duplex (FDD) applications, time division duplex (TDD) applications, carrier-aggregation (CA) applications, multiple antenna applications, MIMO applications, hybrid applications, applications supporting multiple communications bands, the like, or any combination thereof.

FIG. 1 shows traditional communications circuitry 10 according to the prior art. The traditional communications circuitry 10 illustrated in FIG. 1 is a time-division duplex (TDD) system, which is capable of transmitting and receiving RF signals, but not simultaneously. Such a system may also be called a half-duplex system. Additionally, the traditional communications circuitry 10 may be used as a simplex system, which is a system that only transmits RF signals or only receives RF signals. Traditional communications systems often use fixed frequency filters. As a result, to cover multiple communications bands, switching elements are needed to select between different signal paths.

The traditional communications circuitry 10 includes traditional RF system control circuitry 12, traditional RF front-end circuitry 14, and a first RF antenna 16. The traditional RF front-end circuitry 14 includes traditional RF front-end control circuitry 18, first traditional antenna matching circuitry 20, first traditional RF receive circuitry 22, first traditional RF transmit circuitry 24, a first traditional RF switch 26, and a second traditional RF switch 28. The first traditional RF switch 26 is coupled between the first traditional antenna matching circuitry 20 and the first traditional RF receive circuitry 22. The second traditional RF switch 28 is coupled between the first traditional antenna matching circuitry 20 and the first traditional RF transmit circuitry 24. The first RF antenna 16 is coupled to the first traditional antenna matching circuitry 20. The first traditional antenna matching circuitry 20 provides at least partial impedance matching between the first RF antenna 16 and either the first traditional RF receive circuitry 22 or the first traditional RF transmit circuitry 24.

The traditional RF system control circuitry 12 provides the necessary control functions needed to facilitate RF communications between the traditional communications circuitry 10 and other RF devices. The traditional RF system control circuitry 12 processes baseband signals needed for the RF communications. As such, the traditional RF system control circuitry 12 provides a first traditional upstream transmit signal TUT1 to the first traditional RF transmit circuitry 24. The first traditional upstream transmit signal TUT1 may be a baseband transmit signal, an intermediate frequency (IF) transmit signal, or an RF transmit signal. Conversely, the traditional RF system control circuitry 12 receives a first traditional downstream receive signal TDR1 from the first traditional RF receive circuitry 22. The first traditional downstream receive signal TDR1 may be a baseband receive signal, an IF receive signal, or an RF receive signal.

The first traditional RF transmit circuitry 24 may include up-conversion circuitry, amplification circuitry, power supply circuitry, filtering circuitry, switching circuitry, combining circuitry, splitting circuitry, dividing circuitry, clocking circuitry, the like, or any combination thereof. Similarly, the first traditional RF receive circuitry 22 may include down-conversion circuitry, amplification circuitry, power supply circuitry, filtering circuitry, switching circuitry, combining circuitry, splitting circuitry, dividing circuitry, clocking circuitry, the like, or any combination thereof.

The traditional RF system control circuitry 12 provides a traditional front-end control signal TFEC to the traditional RF front-end control circuitry 18. The traditional RF front-end control circuitry 18 provides a first traditional switch control signal TCS1 and a second traditional switch control signal TCS2 to the first traditional RF switch 26 and the second traditional RF switch 28, respectively, based on the traditional front-end control signal TFEC. As such, the traditional RF system control circuitry 12 controls the first traditional RF switch 26 and the second traditional RF switch 28 via the traditional front-end control signal TFEC. The first traditional RF switch 26 is in one of an ON state and an OFF state based on the first traditional switch control signal TCS1. The second traditional RF switch 28 is in one of an ON state and an OFF state based on the second traditional switch control signal TCS2.

Half-duplex operation of the traditional communications circuitry 10 is accomplished using the first traditional RF switch 26 and the second traditional RF switch 28. When the traditional communications circuitry 10 is transmitting RF signals via the first RF antenna 16, the first traditional RF switch 26 is in the OFF state and the second traditional RF switch 28 is in the ON state. As such, the first traditional antenna matching circuitry 20 is electrically isolated from the first traditional RF receive circuitry 22 and the first traditional antenna matching circuitry 20 is electrically coupled to the first traditional RF transmit circuitry 24. In this regard, the traditional RF system control circuitry 12 provides the first traditional upstream transmit signal TUT1 to the first traditional RF transmit circuitry 24, which provides a traditional transmit signal TTX to the first RF antenna 16 via the second traditional RF switch 28 and the first traditional antenna matching circuitry 20 based on the first traditional upstream transmit signal TUT1.

When the traditional communications circuitry 10 is receiving RF signals via the first RF antenna 16, the first traditional RF switch 26 is in the ON state and the second traditional RF switch 28 is in the OFF state. As such, the first traditional antenna matching circuitry 20 is isolated from the first traditional RF transmit circuitry 24 and the first traditional antenna matching circuitry 20 is electrically coupled to the first traditional RF receive circuitry 22. In this regard, the first traditional antenna matching circuitry 20 receives the RF signals from the first RF antenna 16 and forwards the RF signals via the first traditional RF switch 26 to the first traditional RF receive circuitry 22. The first traditional RF switch 26 provides a traditional receive signal TRX to the first traditional RF receive circuitry 22, which provides a first traditional downstream receive signal TDR1 to the traditional RF system control circuitry 12 based on the traditional receive signal TRX.

Since the traditional communications circuitry 10 illustrated in FIG. 1 is a half-duplex system, during operation, the first traditional RF switch 26 and the second traditional RF switch 28 are not simultaneously in the ON state. Therefore, the first traditional RF receive circuitry 22 and the first traditional RF transmit circuitry 24 are isolated from one another. As such, the first traditional RF receive circuitry 22 and the first traditional RF transmit circuitry 24 are prevented from interfering with one another.

FIG. 2 shows the traditional communications circuitry 10 according to the prior art. The traditional communications circuitry 10 illustrated in FIG. 2 is similar to the traditional communications circuitry 10 illustrated in FIG. 1, except in the traditional communications circuitry 10 illustrated in FIG. 2, the traditional RF front-end control circuitry 18, the first traditional RF switch 26, and the second traditional RF switch 28 are omitted, and the traditional RF front-end circuitry 14 further includes a first traditional RF duplexer 30. The first traditional RF duplexer 30 is coupled between the first traditional antenna matching circuitry 20 and the first traditional RF receive circuitry 22, and is further coupled between the first traditional antenna matching circuitry 20 and the first traditional RF transmit circuitry 24.

The traditional communications circuitry 10 illustrated in FIG. 2 may be used as a TDD system or a simplex system. However, the traditional communications circuitry 10 illustrated in FIG. 2 may also be used as a frequency-division duplex (FDD) system, which is capable of transmitting and receiving RF signals simultaneously. Such a system may also be called a full-duplex system.

When the traditional communications circuitry 10 is transmitting RF signals via the first RF antenna 16, the traditional RF system control circuitry 12 provides the first traditional upstream transmit signal TUT1 to the first traditional RF transmit circuitry 24, which provides the traditional transmit signal TTX to the first RF antenna 16 via first traditional RF duplexer 30 based on the first traditional upstream transmit signal TUT1.

When the traditional communications circuitry 10 is receiving RF signals via the first RF antenna 16, the first traditional antenna matching circuitry 20 receives the RF signals from the first RF antenna 16 and forwards the RF signals via the first traditional RF duplexer 30 to the first traditional RF receive circuitry 22. As such, the first traditional RF duplexer 30 provides the traditional receive signal TRX to the first traditional RF receive circuitry 22, which provides the first traditional downstream receive signal TDR1 to the traditional RF system control circuitry 12 based on the traditional receive signal TRX.

The first traditional RF duplexer 30 provides filtering, such that the first traditional RF receive circuitry 22 and the first traditional RF transmit circuitry 24 are substantially isolated from one another. As such, the first traditional RF receive circuitry 22 and the first traditional RF transmit circuitry 24 are prevented from interfering with one another. Traditional FDD systems using duplexers with high rejection ratios have a fixed frequency transfer. Covering multiple communications bands requires multiple duplexers and switches to route RF signals through appropriate signal paths.

FIG. 3 shows the traditional communications circuitry 10 according to the prior art. The traditional communications circuitry 10 illustrated in FIG. 3 is a carrier aggregation (CA) based system, which is capable of transmitting or receiving multiple simultaneous transmit signals or multiple simultaneous receive signals, respectively, or both. Each of the simultaneous transmit signals is in a frequency band that is different from each frequency band of a balance of the simultaneous transmit signals. Similarly, each of the simultaneous receive signals is in a frequency band that is different from each frequency band of a balance of the simultaneous receive signals. The traditional communications circuitry 10 may operate as a simplex system, a half-duplex system, or a full-duplex system.

The traditional communications circuitry 10 includes the traditional RF system control circuitry 12, the traditional RF front-end circuitry 14, the first RF antenna 16, and a second RF antenna 32. The traditional RF front-end circuitry 14 includes the first traditional antenna matching circuitry 20, the first traditional RF receive circuitry 22, the first traditional RF transmit circuitry 24, the first traditional RF duplexer 30, first traditional antenna switching circuitry 34, a second traditional RF duplexer 36, a third traditional RF duplexer 38, second traditional antenna matching circuitry 40, second traditional antenna switching circuitry 42, a fourth traditional RF duplexer 44, a fifth traditional RF duplexer 46, a sixth traditional RF duplexer 48, second traditional RF receive circuitry 50, and second traditional RF transmit circuitry 52. Traditional CA systems use fixed frequency filters and diplexers, triplexers, or both to combine signal paths, which increases complexity. Alternatively, additional switch paths may be used, but may degrade performance.

The first traditional antenna matching circuitry 20 is coupled between the first RF antenna 16 and the first traditional antenna switching circuitry 34. The second traditional antenna matching circuitry 40 is coupled between the second RF antenna 32 and the second traditional antenna switching circuitry 42. The first traditional RF duplexer 30 is coupled between the first traditional antenna switching circuitry 34 and the first traditional RF receive circuitry 22, and is further coupled between the first traditional antenna switching circuitry 34 and the first traditional RF transmit circuitry 24. The second traditional RF duplexer 36 is coupled between the first traditional antenna switching circuitry 34 and the first traditional RF receive circuitry 22, and is further coupled between the first traditional antenna switching circuitry 34 and the first traditional RF transmit circuitry 24. The third traditional RF duplexer 38 is coupled between the first traditional antenna switching circuitry 34 and the first traditional RF receive circuitry 22, and is further coupled between the first traditional antenna switching circuitry 34 and the first traditional RF transmit circuitry 24.

The fourth traditional RF duplexer 44 is coupled between the second traditional antenna switching circuitry 42 and the second traditional RF receive circuitry 50, and is further coupled between the second traditional antenna switching circuitry 42 and the second traditional RF transmit circuitry 52. The fifth traditional RF duplexer 46 is coupled between the second traditional antenna switching circuitry 42 and the second traditional RF receive circuitry 50, and is further coupled between the second traditional antenna switching circuitry 42 and the second traditional RF transmit circuitry 52. The sixth traditional RF duplexer 48 is coupled between the second traditional antenna switching circuitry 42 and the second traditional RF receive circuitry 50, and is further coupled between the second traditional antenna switching circuitry 42 and the second traditional RF transmit circuitry 52.

The first traditional RF duplexer 30 is associated with a first aggregated receive band, a first aggregated transmit band, or both. The second traditional RF duplexer 36 is associated with a second aggregated receive band, a second aggregated transmit band, or both. The third traditional RF duplexer 38 is associated with a third aggregated receive band, a third aggregated transmit band, or both. The fourth traditional RF duplexer 44 is associated with a fourth aggregated receive band, a fourth aggregated transmit band, or both. The fifth traditional RF duplexer 46 is associated with a fifth aggregated receive band, a fifth aggregated transmit band, or both. The sixth traditional RF duplexer 48 is associated with a sixth aggregated receive band, a sixth aggregated transmit band, or both.

The first traditional antenna switching circuitry 34 couples a selected one of the first traditional RF duplexer 30, the second traditional RF duplexer 36, and the third traditional RF duplexer 38 to the first traditional antenna matching circuitry 20. Therefore, the first RF antenna 16 is associated with a selected one of the first aggregated receive band, the second aggregated receive band, and the third aggregated receive band; with a selected one of the first aggregated transmit band, the second aggregated transmit band, and the third aggregated transmit band; or both.

Similarly, the second traditional antenna switching circuitry 42 couples a selected one of the fourth traditional RF duplexer 44, the fifth traditional RF duplexer 46, and the sixth traditional RF duplexer 48 to the second traditional antenna matching circuitry 40. Therefore, the second RF antenna 32 is associated with a selected one of the fourth aggregated receive band, the fifth aggregated receive band, and the sixth aggregated receive band; with a selected one of the fourth aggregated transmit band, the fifth aggregated transmit band, and the sixth aggregated transmit band; or both.

During transmit CA, the traditional RF system control circuitry 12 provides the first traditional upstream transmit signal TUT1 to the first traditional RF transmit circuitry 24, which forwards the first traditional upstream transmit signal TUT1 to the first RF antenna 16 for transmission via the selected one of the first traditional RF duplexer 30, the second traditional RF duplexer 36, and the third traditional RF duplexer 38; via the first traditional antenna switching circuitry 34; and via the first traditional antenna matching circuitry 20.

Additionally, during transmit CA, the traditional RF system control circuitry 12 provides a second traditional upstream transmit signal TUT2 to the second traditional RF transmit circuitry 52, which forwards the second traditional upstream transmit signal TUT2 to the second RF antenna 32 for transmission via the selected one of the fourth traditional RF duplexer 44, the fifth traditional RF duplexer 46, and the sixth traditional RF duplexer 48; via the second traditional antenna switching circuitry 42; and via the second traditional antenna matching circuitry 40.

During receive CA, the first RF antenna 16 forwards a received RF signal to the first traditional RF receive circuitry 22 via the first traditional antenna matching circuitry 20, the first traditional antenna switching circuitry 34, and the selected one of the first traditional RF duplexer 30, the second traditional RF duplexer 36, and the third traditional RF duplexer 38. The first traditional RF receive circuitry 22 provides the first traditional downstream receive signal TDR1 to the traditional RF system control circuitry 12 based on the received RF signal.

Additionally, during receive CA, the second RF antenna 32 forwards a received RF signal to the second traditional RF receive circuitry 50 via the second traditional antenna matching circuitry 40, the second traditional antenna switching circuitry 42, and the selected one of the fourth traditional RF duplexer 44, the fifth traditional RF duplexer 46, and the sixth traditional RF duplexer 48. The second traditional RF receive circuitry 50 provides a second traditional downstream receive signal TDR2 to the traditional RF system control circuitry 12 based on the received RF signal.

Since only the selected one of the first traditional RF duplexer 30, the second traditional RF duplexer 36, and the third traditional RF duplexer 38 is coupled to the first traditional antenna matching circuitry 20; the first traditional antenna switching circuitry 34 isolates each of the first traditional RF duplexer 30, the second traditional RF duplexer 36, and the third traditional RF duplexer 38 from one another; and prevents each of the first traditional RF duplexer 30, the second traditional RF duplexer 36, and the third traditional RF duplexer 38 from interfering with one another.

Similarly, since only the selected one of the fourth traditional RF duplexer 44, the fifth traditional RF duplexer 46, and the sixth traditional RF duplexer 48 is coupled to the second traditional antenna matching circuitry 40; the second traditional antenna matching circuitry 40 isolates each of the fourth traditional RF duplexer 44, the fifth traditional RF duplexer 46, and the sixth traditional RF duplexer 48 from one another; and prevents each of the fourth traditional RF duplexer 44, the fifth traditional RF duplexer 46, and the sixth traditional RF duplexer 48 from interfering with one another.

FIG. 4 shows RF communications circuitry 54 according to one embodiment of the RF communications circuitry 54. The RF communications circuitry 54 includes RF system control circuitry 56, RF front-end circuitry 58, and the first RF antenna 16. The RF front-end circuitry 58 includes a first RF filter structure 60, RF receive circuitry 62, and RF transmit circuitry 64. The first RF filter structure 60 includes a first tunable RF filter path 66 and a second tunable RF filter path 68. Additionally, the first RF filter structure 60 has a first connection node 70, a second connection node 72, and a first common connection node 74. In one embodiment of the RF system control circuitry 56, the RF system control circuitry 56 is an RF transceiver. In one embodiment of the first tunable RF filter path 66, the first tunable RF filter path 66 includes a pair of weakly coupled resonators R(1,1), R(1,2) (FIG. 22). As such, in one embodiment of the first RF filter structure 60, the RF filter structure 60 includes the pair of weakly coupled resonators R(1,1), R(1,2) (FIG. 21).

In alternate embodiments of the first RF filter structure 60, any or all of the first connection node 70, the second connection node 72, and the first common connection node 74 are external to the first RF filter structure 60. In one embodiment of the first tunable RF filter path 66, the first tunable RF filter path 66 includes a first pair (not shown) of weakly coupled resonators. In one embodiment of the second tunable RF filter path 68, the second tunable RF filter path 68 includes a second pair (not shown) of weakly coupled resonators.

In one embodiment of the first RF filter structure 60, the first tunable RF filter path 66 is directly coupled between the first common connection node 74 and the first connection node 70, the second tunable RF filter path 68 is directly coupled between the second connection node 72 and the first common connection node 74, and the first RF antenna 16 is directly coupled to the first common connection node 74. In another embodiment of the RF communications circuitry 54, the first RF antenna 16 is omitted. Additionally, the RF receive circuitry 62 is coupled between the first connection node 70 and the RF system control circuitry 56, and the RF transmit circuitry 64 is coupled between the second connection node 72 and the RF system control circuitry 56.

In one embodiment of the RF communications circuitry 54, the first tunable RF filter path 66 is a first RF receive filter, such that the first RF antenna 16 forwards a received RF signal via the first common connection node 74 to provide a first upstream RF receive signal RU1 to the first tunable RF filter path 66, which receives and filters the first upstream RF receive signal RU1 to provide a first filtered RF receive signal RF1 to the RF receive circuitry 62. The RF receive circuitry 62 may include down-conversion circuitry, amplification circuitry, power supply circuitry, filtering circuitry, switching circuitry, combining circuitry, splitting circuitry, dividing circuitry, clocking circuitry, the like, or any combination thereof. The RF receive circuitry 62 processes the first filtered RF receive signal RF1 to provide a first receive signal RX1 to the RF system control circuitry 56.

In one embodiment of the RF communications circuitry 54, the second tunable RF filter path 68 is a first RF transmit filter, such that the RF system control circuitry 56 provides a first transmit signal TX1 to the RF transmit circuitry 64, which processes the first transmit signal TX1 to provide a first upstream RF transmit signal TU1 to the second tunable RF filter path 68. The RF transmit circuitry 64 may include up-conversion circuitry, amplification circuitry, power supply circuitry, filtering circuitry, switching circuitry, combining circuitry, splitting circuitry, dividing circuitry, clocking circuitry, the like, or any combination thereof. The second tunable RF filter path 68 receives and filters the first upstream RF transmit signal TU1 to provide a first filtered RF transmit signal TF1, which is transmitted via the first common connection node 74 by the first RF antenna 16.

The RF system control circuitry 56 provides a first filter control signal FCS1 to the first tunable RF filter path 66 and provides a second filter control signal FCS2 to the second tunable RF filter path 68. As such, in one embodiment of the RF communications circuitry 54, the RF system control circuitry 56 tunes a first filter parameter of the first tunable RF filter path 66 using the first filter control signal FCS1. Additionally, the RF system control circuitry 56 tunes a first filter parameter of the second tunable RF filter path 68 using the second filter control signal FCS2.

In one embodiment of the RF communications circuitry 54, the first tunable RF filter path 66 and the second tunable RF filter path 68 do not significantly load one another at frequencies of interest. As such, by directly coupling the first tunable RF filter path 66 and the second tunable RF filter path 68 to the first common connection node 74; front-end RF switching elements may be avoided, thereby reducing cost, size, and non-linearity; and increasing efficiency and flexibility of the RF communications circuitry 54. Since tunable RF filters can support multiple communications bands using a single signal path, they can simplify front-end architectures by eliminating switching and duplexing components.

In one embodiment of the RF communications circuitry 54, the RF communications circuitry 54 is used as an FDD communications system, such that the first upstream RF receive signal RU1 and the first filtered RF transmit signal TF1 are full-duplex signals. In an alternate embodiments of the RF communications circuitry 54, the RF communications circuitry 54 is used as a TDD communications system, such that the first upstream RF receive signal RU1 and the first filtered RF transmit signal TF1 are half-duplex signals. In additional embodiments of the RF communications circuitry 54, the RF communications circuitry 54 is used as a simplex communications system, such that the first upstream RF receive signal RU1 is a simplex signal and the first filtered RF transmit signal TF1 is not present. In other embodiments of the RF communications circuitry 54, the RF communications circuitry 54 is used as a simplex communications system, such that the first upstream RF receive signal RU1 is not present and the first filtered RF transmit signal TF1 is a simplex signal.

FIG. 5 is a graph illustrating filtering characteristics of the first tunable RF filter path 66 and the second tunable RF filter path 68 illustrated in FIG. 4 according to one embodiment of the first tunable RF filter path 66 and the second tunable RF filter path 68. The first tunable RF filter path 66 is a first RF bandpass filter, which functions as the first RF receive filter, and the second tunable RF filter path 68 is a second RF bandpass filter, which functions as the first RF transmit filter. A bandwidth 76 of the first RF bandpass filter, a center frequency 78 of the first RF bandpass filter, a bandwidth 80 of the second RF bandpass filter, a center frequency 82 of the second RF bandpass filter, a frequency 84 of the first upstream RF receive signal RU1 (FIG. 4), and a frequency 86 of the first filtered RF transmit signal TF1 (FIG. 4) are shown. Operation of the first RF bandpass filter and the second RF bandpass filter is such that the first RF bandpass filter and the second RF bandpass filter do not significantly interfere with one another. In this regard, the bandwidth 76 of the first RF bandpass filter does not overlap the bandwidth 80 of the second RF bandpass filter.

In one embodiment of the first RF receive filter and the first RF transmit filter, the first RF receive filter and the first RF transmit filter in combination function as an RF duplexer. As such, a duplex frequency 88 of the RF duplexer is about equal to a difference between the frequency 84 of the first upstream RF receive signal RU1 (FIG. 4) and the frequency 86 of the first filtered RF transmit signal TF1 (FIG. 4).

In one embodiment of the first tunable RF filter path 66, the first filter parameter of the first tunable RF filter path 66 is tunable based on the first filter control signal FCS1. In an alternate embodiment of the first tunable RF filter path 66, both the first filter parameter of the first tunable RF filter path 66 and a second filter parameter of the first tunable RF filter path 66 are tunable based on the first filter control signal FCS1. Similarly, in one embodiment of the second tunable RF filter path 68, the first filter parameter of the second tunable RF filter path 68 is tunable based on the second filter control signal FCS2. In an alternate embodiment of the second tunable RF filter path 68, both the first filter parameter of the second tunable RF filter path 68 and a second filter parameter of the second tunable RF filter path 68 are tunable based on the second filter control signal FCS2.

The first filter parameter of the first tunable RF filter path 66 is the center frequency 78 of the first RF bandpass filter. The second filter parameter of the first tunable RF filter path 66 is the bandwidth 76 of the first RF bandpass filter. The first filter parameter of the second tunable RF filter path 68 is the center frequency 82 of the second RF bandpass filter. The second filter parameter of the second tunable RF filter path 68 is the bandwidth 80 of the second RF bandpass filter.

FIGS. 6A and 6B are graphs illustrating filtering characteristics of the first tunable RF filter path 66 and the second tunable RF filter path 68, respectively, illustrated in FIG. 4 according to an alternate embodiment of the first tunable RF filter path 66 and the second tunable RF filter path 68, respectively. The first tunable RF filter path 66 is an RF lowpass filter and the second tunable RF filter path 68 is an RF highpass filter. FIG. 6A shows a frequency response curve 90 of the RF lowpass filter and FIG. 6B shows a frequency response curve 92 of the RF highpass filter. Additionally FIG. 6A shows a break frequency 94 of the RF lowpass filter and FIG. 6B shows a break frequency 96 of the RF highpass filter. Both FIGS. 6A and 6B show the frequency 84 of the first upstream RF receive signal RU1 (FIG. 4), the frequency 86 of the first filtered RF transmit signal TF1 (FIG. 4), and the duplex frequency 88 of the RF duplexer for clarification. However, the RF lowpass filter and the RF highpass filter in combination function as an RF diplexer. The first filter parameter of the first tunable RF filter path 66 is the break frequency 94 of the RF lowpass filter. In one embodiment of the RF lowpass filter, the RF lowpass filter has bandpass filter characteristics. The first filter parameter of the second tunable RF filter path 68 is the break frequency 96 of the RF highpass filter. In one embodiment of the RF highpass filter, the RF highpass filter has bandpass filter characteristics. In one embodiment of the RF diplexer, the break frequency 96 of the RF highpass filter is about equal to the break frequency 94 of the RF lowpass filter.

FIG. 7 shows the RF communications circuitry 54 according to one embodiment of the RF communications circuitry 54. The RF communications circuitry 54 illustrated in FIG. 7 is similar to the RF communications circuitry 54 illustrated in FIG. 4, except in the RF front-end circuitry 58 illustrated in FIG. 7, the RF transmit circuitry 64 (FIG. 4) is omitted and the RF front-end circuitry 58 further includes RF front-end control circuitry 98.

The RF system control circuitry 56 provides a front-end control signal FEC to the RF front-end control circuitry 98. The RF front-end control circuitry 98 provides the first filter control signal FCS1 and the second filter control signal FCS2 based on the front-end control signal FEC. In the RF communications circuitry 54 illustrated in FIG. 4, the RF system control circuitry 56 provides the first filter control signal FCS1 and the second filter control signal FCS2 directly. In general, the RF communications circuitry 54 includes control circuitry, which may be either the RF system control circuitry 56 or the RF front-end control circuitry 98, that provides the first filter control signal FCS1 and the second filter control signal FCS2. As such, in one embodiment of the RF communications circuitry 54, the control circuitry tunes a first filter parameter of the first tunable RF filter path 66 using the first filter control signal FCS1. Additionally, the control circuitry tunes a first filter parameter of the second tunable RF filter path 68 using the second filter control signal FCS2. In an additional embodiment of the RF communications circuitry 54, the control circuitry further tunes a second filter parameter of the first tunable RF filter path 66 using the first filter control signal FCS1; and the control circuitry further tunes a second filter parameter of the second tunable RF filter path 68 using the second filter control signal FCS2.

In alternate embodiments of the first RF filter structure 60, any or all of the first connection node 70, the second connection node 72, and the first common connection node 74 are external to the first RF filter structure 60. In one embodiment of the first tunable RF filter path 66, the first tunable RF filter path 66 includes a first pair (not shown) of weakly coupled resonators. In one embodiment of the second tunable RF filter path 68, the second tunable RF filter path 68 includes a second pair (not shown) of weakly coupled resonators.

In one embodiment of the first RF filter structure 60, the first tunable RF filter path 66 is directly coupled between the first common connection node 74 and the first connection node 70, the second tunable RF filter path 68 is directly coupled between the second connection node 72 and the first common connection node 74, and the first RF antenna 16 is directly coupled to the first common connection node 74. In another embodiment of the RF communications circuitry 54, the first RF antenna 16 is omitted. Additionally, the RF receive circuitry 62 is coupled between the first connection node 70 and the RF system control circuitry 56, and the RF receive circuitry 62 is further coupled between the second connection node 72 and the RF system control circuitry 56.

In one embodiment of the RF communications circuitry 54, the first tunable RF filter path 66 is a first RF receive filter, such that the first RF antenna 16 forwards a first received RF signal via the first common connection node 74 to provide a first upstream RF receive signal RU1 to the first tunable RF filter path 66, which receives and filters the first upstream RF receive signal RU1 to provide a first filtered RF receive signal RF1 to the RF receive circuitry 62. Additionally, the second tunable RF filter path 68 is a second RF receive filter, such that the first RF antenna 16 forwards a second received RF signal via the first common connection node 74 to provide a second upstream RF receive signal RU2 to the second tunable RF filter path 68, which receives and filters the second upstream RF receive signal RU2 to provide a second filtered RF receive signal RF2 to the RF receive circuitry 62.

The RF receive circuitry 62 may include down-conversion circuitry, amplification circuitry, power supply circuitry, filtering circuitry, switching circuitry, combining circuitry, splitting circuitry, dividing circuitry, clocking circuitry, the like, or any combination thereof. The RF receive circuitry 62 processes the first filtered RF receive signal RF1 to provide a first receive signal RX1 to the RF system control circuitry 56. Additionally, the RF receive circuitry 62 processes the second filtered RF receive signal RF2 to provide a second receive signal RX2 to the RF system control circuitry 56.

In one embodiment of the RF communications circuitry 54, the first tunable RF filter path 66 and the second tunable RF filter path 68 do not significantly load one another at frequencies of interest. As such, by directly coupling the first tunable RF filter path 66 and the second tunable RF filter path 68 to the first common connection node 74; front-end RF switching elements may be avoided, thereby reducing cost, size, and non-linearity; and increasing efficiency and flexibility of the RF communications circuitry 54.

In this regard, in one embodiment of the first tunable RF filter path 66 and the second tunable RF filter path 68, each of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a bandpass filter having a unique center frequency. As such, the first filter parameter of each of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a unique center frequency.

In an alternate embodiment of the first tunable RF filter path 66 and the second tunable RF filter path 68, one of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a lowpass filter, and another of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a highpass filter. As such, the first filter parameter of each of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a break frequency.

In an additional embodiment of the first tunable RF filter path 66 and the second tunable RF filter path 68, one of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a lowpass filter, and another of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a bandpass filter. As such, the first filter parameter of one of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a center frequency, and the first filter parameter of another of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a break frequency.

In an additional embodiment of the first tunable RF filter path 66 and the second tunable RF filter path 68, one of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a highpass filter, and another of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a bandpass filter. As such, the first filter parameter of one of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a center frequency, and the first filter parameter of another of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a break frequency.

In one embodiment of the RF communications circuitry 54, the RF communications circuitry 54 is a receive only CA system, such that the first tunable RF filter path 66, which is the first RF receive filter, and the second tunable RF filter path 68, which is the second RF receive filter, simultaneously receive and filter the first upstream RF receive signal RU1 and the second upstream RF receive signal RU2, respectively, via the first common connection node 74. As such, the first RF filter structure 60 functions as a de-multiplexer. In this regard, each of the first upstream RF receive signal RU1 and the second upstream RF receive signal RU2 has a unique carrier frequency. Using receive CA may increase an effective receive bandwidth of the RF communications circuitry 54.

In another embodiment of the RF communications circuitry 54, the RF communications circuitry 54 is a receive only communications system, such that the first tunable RF filter path 66, which is the first RF receive filter, and the second tunable RF filter path 68, which is the second RF receive filter, do not simultaneously receive and filter the first upstream RF receive signal RU1 and the second upstream RF receive signal RU2, respectively. As such, the first upstream RF receive signal RU1 and the second upstream RF receive signal RU2 are nonsimultaneous signals. Each of the first upstream RF receive signal RU1 and the second upstream RF receive signal RU2 may be associated with a unique RF communications band.

FIG. 8 shows the RF communications circuitry 54 according to an alternate embodiment of the RF communications circuitry 54. The RF communications circuitry 54 illustrated in FIG. 8 is similar to the RF communications circuitry 54 illustrated in FIG. 7, except in the RF front-end circuitry 58 illustrated in FIG. 8, the RF receive circuitry 62 is omitted and the RF transmit circuitry 64 is included.

The RF system control circuitry 56 provides the front-end control signal FEC to the RF front-end control circuitry 98. The RF front-end control circuitry 98 provides the first filter control signal FCS1 and the second filter control signal FCS2 based on the front-end control signal FEC. In the RF communications circuitry 54 illustrated in FIG. 4, the RF system control circuitry 56 provides the first filter control signal FCS1 and the second filter control signal FCS2 directly. In general, the RF communications circuitry 54 includes control circuitry, which may be either the RF system control circuitry 56 or the RF front-end control circuitry 98, that provides the first filter control signal FCS1 and the second filter control signal FCS2. As such, in one embodiment of the RF communications circuitry 54, the control circuitry tunes a first filter parameter of the first tunable RF filter path 66 using the first filter control signal FCS1. Additionally, the control circuitry tunes a first filter parameter of the second tunable RF filter path 68 using the second filter control signal FCS2. In an additional embodiment of the RF communications circuitry 54, the control circuitry further tunes a second filter parameter of the first tunable RF filter path 66 using the first filter control signal FCS1; and the control circuitry further tunes a second filter parameter of the second tunable RF filter path 68 using the second filter control signal FCS2.

In alternate embodiments of the first RF filter structure 60, any or all of the first connection node 70, the second connection node 72, and the first common connection node 74 are external to the first RF filter structure 60. In one embodiment of the first tunable RF filter path 66, the first tunable RF filter path 66 includes a first pair (not shown) of weakly coupled resonators. In one embodiment of the second tunable RF filter path 68, the second tunable RF filter path 68 includes a second pair (not shown) of weakly coupled resonators.

In one embodiment of the first RF filter structure 60, the first tunable RF filter path 66 is directly coupled between the first common connection node 74 and the first connection node 70, the second tunable RF filter path 68 is directly coupled between the second connection node 72 and the first common connection node 74, and the first RF antenna 16 is directly coupled to the first common connection node 74. In another embodiment of the RF communications circuitry 54, the first RF antenna 16 is omitted. Additionally, the RF transmit circuitry 64 is coupled between the first connection node 70 and the RF system control circuitry 56, and the RF transmit circuitry 64 is further coupled between the second connection node 72 and the RF system control circuitry 56.

In one embodiment of the RF communications circuitry 54, the first tunable RF filter path 66 is a first RF transmit filter, such that the RF system control circuitry 56 provides the first transmit signal TX1 to the RF transmit circuitry 64, which processes the first transmit signal TX1 to provide a first upstream RF transmit signal TU1 to the first tunable RF filter path 66. Similarly, the second tunable RF filter path 68 is a second RF transmit filter, such that the RF system control circuitry 56 provides a second transmit signal TX2 to the RF transmit circuitry 64, which processes the second transmit signal TX2 to provide a second upstream RF transmit signal TU2 to the second tunable RF filter path 68.

The RF transmit circuitry 64 may include up-conversion circuitry, amplification circuitry, power supply circuitry, filtering circuitry, switching circuitry, combining circuitry, splitting circuitry, dividing circuitry, clocking circuitry, the like, or any combination thereof. The first tunable RF filter path 66 receives and filters the first upstream RF transmit signal TU1 to provide the first filtered RF transmit signal TF1, which is transmitted via the first common connection node 74 by the first RF antenna 16. Similarly, the second tunable RF filter path 68 receives and filters the second upstream RF transmit signal TU2 to provide a second filtered RF transmit signal TF2, which is transmitted via the first common connection node 74 by the first RF antenna 16.

In one embodiment of the RF communications circuitry 54, the first tunable RF filter path 66 and the second tunable RF filter path 68 do not significantly load one another at frequencies of interest. As such, by directly coupling the first tunable RF filter path 66 and the second tunable RF filter path 68 to the first common connection node 74; front-end RF switching elements may be avoided, thereby reducing cost, size, and non-linearity; and increasing efficiency and flexibility of the RF communications circuitry 54.

In this regard, in one embodiment of the first tunable RF filter path 66 and the second tunable RF filter path 68, each of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a bandpass filter having a unique center frequency. As such, the first filter parameter of each of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a unique center frequency.

In an alternate embodiment of the first tunable RF filter path 66 and the second tunable RF filter path 68, one of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a lowpass filter, and another of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a highpass filter. As such, the first filter parameter of each of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a break frequency.

In an additional embodiment of the first tunable RF filter path 66 and the second tunable RF filter path 68, one of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a lowpass filter, and another of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a bandpass filter. As such, the first filter parameter of one of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a center frequency, and the first filter parameter of another of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a break frequency.

In an additional embodiment of the first tunable RF filter path 66 and the second tunable RF filter path 68, one of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a highpass filter, and another of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a bandpass filter. As such, the first filter parameter of one of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a center frequency, and the first filter parameter of another of the first tunable RF filter path 66 and the second tunable RF filter path 68 is a break frequency.

In one embodiment of the RF communications circuitry 54, the RF communications circuitry 54 is a transmit only CA system, such that the first tunable RF filter path 66, which is the first RF transmit filter, and the second tunable RF filter path 68, which is the second RF transmit filter, simultaneously receive and filter the first upstream RF transmit signal TU1 and the second upstream RF transmit signal TU2, respectively, to simultaneously provide the first filtered RF transmit signal TF1 and the second filtered RF transmit signal TF2, respectively, via the first common connection node 74. As such, the first RF filter structure 60 functions as a multiplexer. In this regard, each of the first filtered RF transmit signal TF1 and the second filtered RF transmit signal TF2 has a unique carrier frequency. Using transmit CA may increase an effective transmit bandwidth of the RF communications circuitry 54.

In another embodiment of the RF communications circuitry 54, the RF communications circuitry 54 is a transmit only communications system, such that the first tunable RF filter path 66, which is the first RF transmit filter, and the second tunable RF filter path 68, which is the second RF transmit filter, do not simultaneously receive and filter the first upstream RF transmit signal TU1 and the second upstream RF transmit signal TU2, respectively. As such, the first filtered RF transmit signal TF1 and the second filtered RF transmit signal TF2 are nonsimultaneous signals. Each of the first filtered RF transmit signal TF1 and the second filtered RF transmit signal TF2 may be associated with a unique RF communications band.

FIGS. 9A and 9B are graphs illustrating filtering characteristics of the first tunable RF filter path 66 and the second tunable RF filter path 68, respectively, illustrated in FIG. 8 according to an additional embodiment of the first tunable RF filter path 66 and the second tunable RF filter path 68, respectively. FIG. 9A shows a frequency response curve 100 of the first tunable RF filter path 66 and FIG. 9B shows a frequency response curve 102 of the second tunable RF filter path 68. The first tunable RF filter path 66 and the second tunable RF filter path 68 are both bandpass filters having the frequency response curves 100, 102 illustrated in FIGS. 9A and 9B, respectively. In this regard, the first tunable RF filter path 66 and the second tunable RF filter path 68 can be directly coupled to one another via the first common connection node 74 (FIG. 8) without interfering with one another.

FIGS. 10A and 10B are graphs illustrating filtering characteristics of the first traditional RF duplexer 30 and the second traditional RF duplexer 36, respectively, illustrated in FIG. 3 according to the prior art. FIG. 10A shows a frequency response curve 104 of the first traditional RF duplexer 30 and FIG. 10B shows a frequency response curve 106 of the second traditional RF duplexer 36. There is interference 108 between the frequency response curve 104 of the first traditional RF duplexer 30 and the frequency response curve 106 of the second traditional RF duplexer 36 as shown in FIGS. 10A and 10B. In this regard, the first traditional RF duplexer 30 and the second traditional RF duplexer 36 cannot be directly coupled to one another without interfering with one another. To avoid interference between different filters, traditional systems use RF switches to disconnect unused filters.

FIG. 11 shows the RF communications circuitry 54 according to one embodiment of the RF communications circuitry 54. The RF communications circuitry 54 illustrated in FIG. 11 is similar to the RF communications circuitry 54 illustrated in FIG. 8, except in the RF communications circuitry 54 illustrated in FIG. 11, the RF front-end circuitry 58 further includes the RF receive circuitry 62 and the first RF filter structure 60 further includes a third tunable RF filter path 110 and a fourth tunable RF filter path 112. Additionally, the RF front-end circuitry 58 has the first connection node 70, the second connection node 72, the first common connection node 74, a third connection node 114 and a fourth connection node 116, such that all of the first connection node 70, the second connection node 72, the first common connection node 74, the third connection node 114 and the fourth connection node 116 are external to the first RF filter structure 60. In an alternate of the RF front-end circuitry 58, any or all of the first connection node 70, the second connection node 72, the first common connection node 74, a third connection node 114 and a fourth connection node 116 are internal to the first RF filter structure 60.

The RF front-end control circuitry 98 further provides a third filter control signal FCS3 to the third tunable RF filter path 110 and a fourth filter control signal FCS4 to the fourth tunable RF filter path 112 based on the front-end control signal FEC. In one embodiment of the RF communications circuitry 54, the control circuitry tunes a first filter parameter of the third tunable RF filter path 110 using the third filter control signal FCS3. Additionally, the control circuitry tunes a first filter parameter of the fourth tunable RF filter path 112 using the fourth filter control signal FCS4. In an additional embodiment of the RF communications circuitry 54, the control circuitry further tunes a second filter parameter of the third tunable RF filter path 110 using the third filter control signal FCS3; and the control circuitry further tunes a second filter parameter of the fourth tunable RF filter path 112 using the fourth filter control signal FCS4.

In one embodiment of the third tunable RF filter path 110, the third tunable RF filter path 110 includes a third pair (not shown) of weakly coupled resonators. In one embodiment of the fourth tunable RF filter path 112, the fourth tunable RF filter path 112 includes a fourth pair (not shown) of weakly coupled resonators.

In one embodiment of the third tunable RF filter path 110 and the fourth tunable RF filter path 112, the third tunable RF filter path 110 is directly coupled between the first common connection node 74 and the third connection node 114, and the fourth tunable RF filter path 112 is directly coupled between the fourth connection node 116 and the first common connection node 74. In another embodiment of the RF communications circuitry 54, the first RF antenna 16 is omitted. Additionally, the RF receive circuitry 62 is coupled between the third connection node 114 and the RF system control circuitry 56, and the RF receive circuitry 62 is further coupled between the fourth connection node 116 and the RF system control circuitry 56.

In one embodiment of the RF communications circuitry 54, the third tunable RF filter path 110 is the first RF receive filter, such that the first RF antenna 16 forwards a first received RF signal via the first common connection node 74 to provide the first upstream RF receive signal RU1 to the third tunable RF filter path 110, which receives and filters the first upstream RF receive signal RU1 to provide the first filtered RF receive signal RF1 to the RF receive circuitry 62. Additionally, the fourth tunable RF filter path 112 is a second RF receive filter, such that the first RF antenna 16 forwards a second received RF signal via the first common connection node 74 to provide the second upstream RF receive signal RU2 to the fourth tunable RF filter path 112, which receives and filters the second upstream RF receive signal RU2 to provide the second filtered RF receive signal RF2 to the RF receive circuitry 62.

The RF receive circuitry 62 may include down-conversion circuitry, amplification circuitry, power supply circuitry, filtering circuitry, switching circuitry, combining circuitry, splitting circuitry, dividing circuitry, clocking circuitry, the like, or any combination thereof. The RF receive circuitry 62 processes the first filtered RF receive signal RF1 to provide the first receive signal RX1 to the RF system control circuitry 56. Additionally, the RF receive circuitry 62 processes the second filtered RF receive signal RF2 to provide the second receive signal RX2 to the RF system control circuitry 56.

In one embodiment of the RF communications circuitry 54, the first tunable RF filter path 66, the second tunable RF filter path 68, the third tunable RF filter path 110, and the fourth tunable RF filter path 112 do not significantly load one another at frequencies of interest. As such, by directly coupling the first tunable RF filter path 66, the second tunable RF filter path 68, the third tunable RF filter path 110, and the fourth tunable RF filter path 112 to the first common connection node 74; front-end RF switching elements may be avoided, thereby reducing cost, size, and non-linearity; and increasing efficiency and flexibility of the RF communications circuitry 54.

In this regard, in one embodiment of the third tunable RF filter path 110 and the fourth tunable RF filter path 112, each of the third tunable RF filter path 110 and the fourth tunable RF filter path 112 is a bandpass filter having a unique center frequency. As such, the first filter parameter of each of the third tunable RF filter path 110 and the fourth tunable RF filter path 112 is a unique center frequency.

In an alternate embodiment of the third tunable RF filter path 110 and the fourth tunable RF filter path 112, one of the third tunable RF filter path 110 and the fourth tunable RF filter path 112 is a lowpass filter, and another of the third tunable RF filter path 110 and the fourth tunable RF filter path 112 is a highpass filter. As such, the first filter parameter of each of the third tunable RF filter path 110 and the fourth tunable RF filter path 112 is a break frequency.

In an additional embodiment of the third tunable RF filter path 110 and the fourth tunable RF filter path 112, one of the third tunable RF filter path 110 and the fourth tunable RF filter path 112 is a lowpass filter, and another of the third tunable RF filter path 110 and the fourth tunable RF filter path 112 is a bandpass filter. As such, the first filter parameter of one of the third tunable RF filter path 110 and the fourth tunable RF filter path 112 is a center frequency, and the first filter parameter of another of the third tunable RF filter path 110 and the fourth tunable RF filter path 112 is a break frequency.

In an additional embodiment of the third tunable RF filter path 110 and the fourth tunable RF filter path 112, one of the third tunable RF filter path 110 and the fourth tunable RF filter path 112 is a highpass filter, and another of the third tunable RF filter path 110 and the fourth tunable RF filter path 112 is a bandpass filter. As such, the first filter parameter of one of the third tunable RF filter path 110 and the fourth tunable RF filter path 112 is a center frequency, and the first filter parameter of another of the third tunable RF filter path 110 and the fourth tunable RF filter path 112 is a break frequency.

In one embodiment of the RF communications circuitry 54, the RF communications circuitry 54 is a CA system, such that the third tunable RF filter path 110, which is the first RF receive filter, and the fourth tunable RF filter path 112, which is the second RF receive filter, simultaneously receive and filter the first upstream RF receive signal RU1 and the second upstream RF receive signal RU2, respectively, via the first common connection node 74. As such, the first RF filter structure 60 functions as a de-multiplexer using the third tunable RF filter path 110 and the fourth tunable RF filter path 112. In one embodiment of the first RF filter structure 60, the first RF filter structure 60 further functions as a multiplexer using the first tunable RF filter path 66 and the second tunable RF filter path 68. In this regard, each of the first upstream RF receive signal RU1 and the second upstream RF receive signal RU2 has a unique carrier frequency.

In another embodiment of the RF communications circuitry 54, the RF communications circuitry 54 is a receive communications system, such that the third tunable RF filter path 110, which is the first RF receive filter, and the fourth tunable RF filter path 112, which is the second RF receive filter, do not simultaneously receive and filter the first upstream RF receive signal RU1 and the second upstream RF receive signal RU2, respectively. As such, the first upstream RF receive signal RU1 and the second upstream RF receive signal RU2 are nonsimultaneous signals. Each of the first upstream RF receive signal RU1 and the second upstream RF receive signal RU2 may be associated with a unique RF communications band.

FIG. 12 shows the RF communications circuitry 54 according to an alternate embodiment of the RF communications circuitry 54. The RF communications circuitry 54 illustrated in FIG. 12 is similar to the RF communications circuitry 54 illustrated in FIG. 11, except the RF communications circuitry 54 illustrated in FIG. 12 further includes the second RF antenna 32. Additionally, the RF front-end circuitry 58 further includes a second common connection node 118 and a second RF filter structure 120. The third tunable RF filter path 110 and the fourth tunable RF filter path 112 are included in the second RF filter structure 120 instead of being included in the first RF filter structure 60. Instead of being coupled to the first common connection node 74, the third tunable RF filter path 110 and the fourth tunable RF filter path 112 are coupled to the second common connection node 118. In one embodiment of the third tunable RF filter path 110 and the fourth tunable RF filter path 112, the third tunable RF filter path 110 and the fourth tunable RF filter path 112 are directly coupled to the second common connection node 118. In one embodiment of the RF communications circuitry 54, the second RF antenna 32 is coupled to the second common connection node 118.

FIG. 13 shows the RF communications circuitry 54 according to an additional embodiment of the RF communications circuitry 54. The RF communications circuitry 54 illustrated in FIG. 13 is similar to the RF communications circuitry 54 illustrated in FIG. 12, except in the RF communications circuitry 54 illustrated in FIG. 13, the RF front-end control circuitry 98 provides a front-end status signal FES to the RF system control circuitry 56. Additionally, the RF front-end control circuitry 98 provides a first calibration control signal CCS1 and up to and including an N^(TH) calibration control signal CCSN to the first RF filter structure 60. The RF front-end control circuitry 98 provides a P^(TH) calibration control signal CCSP and up to and including an X^(TH) calibration control signal CCSX to the second RF filter structure 120. Details of the first RF filter structure 60 and the second RF filter structure 120 are not shown to simplify FIG. 13.

The first RF filter structure 60 provides a first calibration status signal CSS1 and up to and including a Q^(TH) calibration status signal CSSQ to the RF front-end control circuitry 98. The second RF filter structure 120 provides an R^(TH) calibration status signal CSSR and up to and including a Y^(TH) calibration status signal CSSY to the RF front-end control circuitry 98. In an alternate embodiment of the RF front-end circuitry 58, any or all of the N^(TH) calibration control signal CCSN, the Q^(TH) calibration status signal CSSQ, the X^(TH) calibration control signal CCSX, and the Y^(TH) calibration status signal CSSY are omitted.

In one embodiment of the RF front-end circuitry 58, the RF front-end circuitry 58 operates in one of a normal operating mode and a calibration mode. During the calibration mode, the RF front-end control circuitry 98 performs a calibration of the first RF filter structure 60, the second RF filter structure 120, or both. As such, the RF front-end control circuitry 98 provides any or all of the filter control signals FCS1, FCS2, FCS3, FCS4 and any or all of the calibration control signals CCS1, CCSN, CCSP, CCSX needed for calibration. Further, the RF front-end control circuitry 98 receives any or all of the calibration status signals CSS1, CSSQ, CSSR, CSSY needed for calibration.

During the normal operating mode, the RF front-end control circuitry 98 provides any or all of the filter control signals FCS1, FCS2, FCS3, FCS4 and any or all of the calibration control signals CCS1, CCSN, CCSP, CCSX needed for normal operation. Further, the RF front-end control circuitry 98 receives any or all of the calibration status signals CSS1, CSSQ, CSSR, CSSY needed for normal operation. Any or all of the calibration control signals CCS1, CCSN, CCSP, CCSX may be based on the front-end control signal FEC. The front-end status signal FES may be based on any or all of the calibration status signals CSS1, CSSQ, CSSR, CSSY. Further, during the normal operating mode, the RF front-end circuitry 58 processes signals as needed for normal operation. Other embodiments described in the present disclosure may be associated with normal operation.

The RF communications circuitry 54 illustrated in FIG. 13 includes the first RF antenna 16 and the second RF antenna 32. In general, the RF communications circuitry 54 is a multiple antenna system. A single-input single-output (SISO) antenna system is a system in which RF transmit signals may be transmitted from the first RF antenna 16 and RF receive signals may be received via the second RF antenna 32. In one embodiment of the RF communications circuitry 54, the antenna system in the RF communications circuitry 54 is a SISO antenna system, as illustrated in FIG. 13.

A single-input multiple-output (SIMO) antenna system is a system in which RF transmit signals may be simultaneously transmitted from the first RF antenna 16 and the second RF antenna 32, and RF receive signals may be received via the second RF antenna 32. In an alternate embodiment of the RF communications circuitry 54, the second RF filter structure 120 is coupled to the RF transmit circuitry 64, such that the antenna system in the RF communications circuitry 54 is a SIMO antenna system.

A multiple-input single-output (MISO) antenna system is a system in which RF transmit signals may be transmitted from the first RF antenna 16, and RF receive signals may be simultaneously received via the first RF antenna 16 and the second RF antenna 32. In an additional embodiment of the RF communications circuitry 54, the first RF filter structure 60 is coupled to the RF receive circuitry 62, such that the antenna system in the RF communications circuitry 54 is a MISO antenna system.

A multiple-input multiple-output (MIMO) antenna system is a system in which RF transmit signals may be simultaneously transmitted from the first RF antenna 16 and the second RF antenna 32, and RF receive signals may be simultaneously received via the first RF antenna 16 and the second RF antenna 32. In another embodiment of the RF communications circuitry 54, the second RF filter structure 120 is coupled to the RF transmit circuitry 64 and the first RF filter structure 60 is coupled to the RF receive circuitry 62, such that the antenna system in the RF communications circuitry 54 is a MIMO antenna system.

FIG. 14 shows the RF communications circuitry 54 according to another embodiment of the RF communications circuitry 54. The RF communications circuitry 54 illustrated in FIG. 14 is similar to the RF communications circuitry 54 illustrated in FIG. 11, except in the RF communications circuitry 54 illustrated in FIG. 14, the first RF filter structure 60 further includes a fifth tunable RF filter path 122 and a sixth tunable RF filter path 124, and the RF front-end circuitry 58 further includes a fifth connection node 126 and a sixth connection node 128. Additionally, the RF front-end control circuitry 98 shown in FIG. 11 is not shown in FIG. 14 to simplify FIG. 14.

In one embodiment of the fifth tunable RF filter path 122, the fifth tunable RF filter path 122 includes a fifth pair (not shown) of weakly coupled resonators. In one embodiment of the sixth tunable RF filter path 124, the sixth tunable RF filter path 124 includes a sixth pair (not shown) of weakly coupled resonators.

In one embodiment of the fifth tunable RF filter path 122 and the sixth tunable RF filter path 124, the fifth tunable RF filter path 122 is directly coupled between the first common connection node 74 and the fifth connection node 126, and the sixth tunable RF filter path 124 is directly coupled between the sixth connection node 128 and the first common connection node 74. In another embodiment of the RF communications circuitry 54, the first RF antenna 16 is omitted. Additionally, the RF receive circuitry 62 is further coupled between the sixth connection node 128 and the RF system control circuitry 56, and the RF transmit circuitry 64 is further coupled between the fifth connection node 126 and the RF system control circuitry 56.

In one embodiment of the RF communications circuitry 54, the sixth tunable RF filter path 124 is a third RF receive filter, such that the first RF antenna 16 forwards a third received RF signal via the first common connection node 74 to provide a third upstream RF receive signal RU3 to the sixth tunable RF filter path 124, which receives and filters the third upstream RF receive signal RU3 to provide a third filtered RF receive signal RF3 to the RF receive circuitry 62, which processes the third filtered RF receive signal RF3 to provide the third receive signal RX3 to the RF system control circuitry 56.

In one embodiment of the RF communications circuitry 54, the fifth tunable RF filter path 122 is a third RF transmit filter, such that the RF system control circuitry 56 provides a third transmit signal TX3 to the RF transmit circuitry 64, which processes the third transmit signal TX3 to provide a third upstream RF transmit signal TU3 to the fifth tunable RF filter path 122. The fifth tunable RF filter path 122 receives and filters the third upstream RF transmit signal TU3 to provide a third filtered RF transmit signal TF3, which is transmitted via the first common connection node 74 by the first RF antenna 16.

In one embodiment of the RF communications circuitry 54, the first tunable RF filter path 66, the second tunable RF filter path 68, the third tunable RF filter path 110, the fourth tunable RF filter path 112, the fifth tunable RF filter path 122, and the sixth tunable RF filter path 124 do not significantly load one another at frequencies of interest. Therefore, antenna switching circuitry 34, 42 (FIG. 3) may be avoided. As such, by directly coupling the first tunable RF filter path 66, the second tunable RF filter path 68, the third tunable RF filter path 110, the fourth tunable RF filter path 112, the fifth tunable RF filter path 122 and the sixth tunable RF filter path 124 to the first common connection node 74; front-end RF switching elements may be avoided, thereby reducing cost, size, and non-linearity; and increasing efficiency and flexibility of the RF communications circuitry 54.

In one embodiment of the RF communications circuitry 54, the RF communications circuitry 54 is an FDD communications system, such that each of the first tunable RF filter path 66, the second tunable RF filter path 68, the third tunable RF filter path 110, the fourth tunable RF filter path 112, the fifth tunable RF filter path 122, and the sixth tunable RF filter path 124 is a bandpass filter having a unique center frequency. As such, in one embodiment of the RF system control circuitry 56, the first filter parameter of each of the first tunable RF filter path 66, the second tunable RF filter path 68, the third tunable RF filter path 110, the fourth tunable RF filter path 112, the fifth tunable RF filter path 122, and the sixth tunable RF filter path 124 is a unique center frequency.

FIG. 15 shows the RF communications circuitry 54 according to a further embodiment of the RF communications circuitry 54. The RF communications circuitry 54 illustrated in FIG. 15 is similar to the RF communications circuitry 54 illustrated in FIG. 4, except in the RF communications circuitry 54 illustrated in FIG. 15, the RF front-end circuitry 58 further includes an RF antenna switch 130 and the third connection node 114. Additionally, the first RF filter structure 60 further includes the third tunable RF filter path 110. Instead of the first RF antenna 16 being directly coupled to the first common connection node 74, as illustrated in FIG. 4, the RF antenna switch 130 is coupled between the first RF antenna 16 and the first common connection node 74. As such, the first common connection node 74 is coupled to the first RF antenna 16 via the RF antenna switch 130. In this regard, the RF communications circuitry 54 is a hybrid RF communications system.

The RF antenna switch 130 has an antenna switch common connection node 132, an antenna switch first connection node 134, an antenna switch second connection node 136, and an antenna switch third connection node 138. The antenna switch common connection node 132 is coupled to the first RF antenna 16. In one embodiment of the RF antenna switch 130, the antenna switch common connection node 132 is directly coupled to the first RF antenna 16. The antenna switch first connection node 134 is coupled to the first common connection node 74. In one embodiment of the RF antenna switch 130, the antenna switch first connection node 134 is directly coupled to the first common connection node 74. The antenna switch second connection node 136 may be coupled to other circuitry (not shown). The antenna switch third connection node 138 may be coupled to other circuitry (not shown). In another embodiment of the RF antenna switch 130, the antenna switch third connection node 138 is omitted. In a further embodiment of the RF antenna switch 130, the RF antenna switch 130 has at least one additional connection node.

The RF system control circuitry 56 provides a switch control signal SCS to the RF antenna switch 130. As such, the RF system control circuitry 56 selects one of the antenna switch first connection node 134, the antenna switch second connection node 136, and the antenna switch third connection node 138 to be coupled to the antenna switch common connection node 132 using the switch control signal SCS.

The third tunable RF filter path 110 is directly coupled between the first common connection node 74 and the third connection node 114. In one embodiment of the RF communications circuitry 54, the third tunable RF filter path 110 is a second RF receive filter, such that the first RF antenna 16 forwards a received RF signal via the RF antenna switch 130 and the first common connection node 74 to provide the second upstream RF receive signal RU2 to the third tunable RF filter path 110, which receives and filters the second upstream RF receive signal RU2 to provide the second filtered RF receive signal RF2 to the RF receive circuitry 62. The RF receive circuitry 62 processes the second filtered RF receive signal RF2 to provide a second receive signal RX2 to the RF system control circuitry 56.

The RF system control circuitry 56 further provides the third filter control signal FCS3. As such, in one embodiment of the RF communications circuitry 54, the RF system control circuitry 56 tunes a first filter parameter of the third tunable RF filter path 110 using the third filter control signal FCS3. In one embodiment of the RF communications circuitry 54, the RF communications circuitry 54 uses the second tunable RF filter path 68 and the third tunable RF filter path 110 to provide receive CA. In an alternate embodiment of the RF communications circuitry 54, tunable RF filters allow for sharing a signal path to provide both an FDD signal path and a TDD signal path, thereby lowering front-end complexity.

FIG. 16 shows the RF communications circuitry 54 according to one embodiment of the RF communications circuitry 54. The RF communications circuitry 54 illustrated in FIG. 16 is similar to the RF communications circuitry 54 illustrated in FIG. 15, except in the RF communications circuitry 54 illustrated in FIG. 16, the third tunable RF filter path 110 is omitted. Additionally, in one embodiment of the RF communications circuitry 54, the RF receive circuitry 62, the RF transmit circuitry 64, and the first RF filter structure 60 are all broadband devices. As such, the RF communications circuitry 54 is broadband circuitry capable of processing RF signals having wide frequency ranges.

FIG. 17 shows the RF communications circuitry 54 according to an alternate embodiment of the RF communications circuitry 54. The RF communications circuitry 54 illustrated in FIG. 17 is similar to the RF communications circuitry 54 illustrated in FIG. 16, except in the RF communications circuitry 54 illustrated in FIG. 17, the RF receive circuitry 62 is omitted and the RF front-end circuitry 58 further includes a first RF front-end circuit 140, a second RF front-end circuit 142, and a third RF front-end circuit 144.

The first RF front-end circuit 140 includes the RF transmit circuitry 64. The second RF front-end circuit 142 includes the first RF filter structure 60, the first connection node 70, the second connection node 72, and the first common connection node 74. The third RF front-end circuit 144 includes the RF antenna switch 130. In one embodiment of the first RF front-end circuit 140, the first RF front-end circuit 140 is a first RF front-end integrated circuit (IC). In one embodiment of the second RF front-end circuit 142, the second RF front-end circuit 142 is a second RF front-end IC. In one embodiment of the third RF front-end circuit 144, the third RF front-end circuit 144 is a third RF front-end IC.

FIG. 18 shows the RF communications circuitry 54 according to an additional embodiment of the RF communications circuitry 54. The RF communications circuitry 54 illustrated in FIG. 18 is similar to the RF communications circuitry 54 illustrated in FIG. 16, except in the RF communications circuitry 54 illustrated in FIG. 18, the RF receive circuitry 62 is omitted and the RF front-end circuitry 58 further includes the first RF front-end circuit 140 and the second RF front-end circuit 142.

The first RF front-end circuit 140 includes the RF transmit circuitry 64. The second RF front-end circuit 142 includes the first RF filter structure 60, the RF antenna switch 130, the first connection node 70, the second connection node 72, and the first common connection node 74. In one embodiment of the first RF front-end circuit 140, the first RF front-end circuit 140 is the first RF front-end IC. In one embodiment of the second RF front-end circuit 142, the second RF front-end circuit 142 is the second RF front-end IC.

FIG. 19 shows the RF communications circuitry 54 according to another embodiment of the RF communications circuitry 54. The RF communications circuitry 54 illustrated in FIG. 19 is similar to the RF communications circuitry 54 illustrated in FIG. 16, except in the RF communications circuitry 54 illustrated in FIG. 19, the RF receive circuitry 62 is omitted and the RF front-end circuitry 58 further includes the first RF front-end circuit 140.

The first RF front-end circuit 140 includes the RF transmit circuitry 64, the first RF filter structure 60, the RF antenna switch 130, the first connection node 70, the second connection node 72, and the first common connection node 74. In one embodiment of the first RF front-end circuit 140, the first RF front-end circuit 140 is the first RF front-end IC.

FIG. 20 shows the RF communications circuitry 54 according to a further embodiment of the RF communications circuitry 54. The RF communications circuitry 54 illustrated in FIG. 20 is a TDD system, which is capable of transmitting and receiving RF signals, but not simultaneously. As such, the RF communications circuitry 54 illustrated in FIG. 20 is similar to the RF communications circuitry 54 illustrated in FIG. 4, except in the RF communications circuitry 54 illustrated in FIG. 20, the second tunable RF filter path 68 and the second connection node 72 are omitted, and the RF front-end circuitry 58 further includes an RF transmit/receive switch 146 coupled between the first tunable RF filter path 66 and the RF receive circuitry 62, and further coupled between the first tunable RF filter path 66 and the RF transmit circuitry 64.

Since the RF communications circuitry 54 does not simultaneously transmit and receive RF signals, the first tunable RF filter path 66 provides front-end transmit filtering when the RF communications circuitry 54 is transmitting RF signals and the first tunable RF filter path 66 provides front-end receive filtering when the RF communications circuitry 54 is receiving RF signals. In this regard, the first tunable RF filter path 66 processes half-duplex signals.

The RF transmit/receive switch 146 has a transmit/receive switch common connection node 148, a transmit/receive switch first connection node 150, and a transmit/receive switch second connection node 152. The RF receive circuitry 62 is coupled between the RF system control circuitry 56 and the transmit/receive switch second connection node 152. The RF transmit circuitry 64 is coupled between the RF system control circuitry 56 and the transmit/receive switch first connection node 150. The first connection node 70 is coupled to the transmit/receive switch common connection node 148.

The RF system control circuitry 56 provides a switch control signal SCS to the RF transmit/receive switch 146. As such, the RF system control circuitry 56 selects either the transmit/receive switch first connection node 150 or the transmit/receive switch second connection node 152 to be coupled to the transmit/receive switch common connection node 148 using the switch control signal SCS. Therefore, when the RF communications circuitry 54 is transmitting RF signals, the RF transmit circuitry 64 is coupled to the first tunable RF filter path 66 and the RF receive circuitry 62 is not coupled to the first tunable RF filter path 66. Conversely, when the RF communications circuitry 54 is receiving RF signals, the RF receive circuitry 62 is coupled to the first tunable RF filter path 66 and the RF transmit circuitry 64 is not coupled to the first tunable RF filter path 66.

FIG. 21 illustrates an exemplary embodiment of the first RF filter structure 60. The first RF filter structure 60 includes a plurality of resonators (referred to generically as elements R and specifically as elements R(i,j), where an integer i indicates a row position and an integer j indicates a column position, where 1≦i≦M, 1≦j≦N and M is any integer greater than 1 and N is any integer greater than to 1. It should be noted that in alternative embodiments the number of resonators R in each row and column may be the same or different). The first tunable RF filter path 66 includes row 1 of weakly coupled resonators R(1,1), R(1,2) through (R(1,N). All of the weakly coupled resonators R(1,1), R(1,2) through (R(1,N) are weakly coupled to one another. Furthermore, the first tunable RF filter path 66 is electrically connected between terminal 200 and terminal 202. In this manner, the first tunable RF filter path 66 is configured to receive RF signals and output filtered RF signals. The second tunable RF filter path 68 includes row M of weakly coupled resonators R(M,1), R(M,2) through R(M,N). All of the weakly coupled resonators R(M,1), R(M,2) through R(M,N) are weakly coupled to one another. Furthermore, the second tunable RF filter path 68 is electrically connected between terminal 204 and terminal 206. In this manner, the second tunable RF filter path 68 is configured to receive RF signals and output filtered RF signals. It should be noted that the first RF filter structure 60 may include any number of tunable RF filter paths, such as, for example, the third tunable RF filter path 110, the fourth tunable RF filter path 112, the fifth tunable RF filter path 122, and the sixth tunable RF filter path 124, described above with respect to FIGS. 11-14. Each of the resonators R may be a tunable resonator, which allows for a resonant frequency of each of the resonators R to be varied to along a frequency range. In some embodiments, not all of the couplings between the resonators R are weak. A hybrid architecture having at least one pair of weakly coupled resonators R and strongly or moderately coupled resonators R is also possible.

Cross-coupling capacitive structures C are electrically connected to and between the resonators R. In this embodiment, each of the cross-coupling capacitive structures C is a variable cross-coupling capacitive structure, such as a varactor or an array of capacitors. To be independent, the magnetic couplings may be negligible. Alternatively, the cross-coupling capacitive structures C may simply be provided by a capacitor with a fixed capacitance. With regard to the exemplary embodiment shown in FIG. 21, the tunable RF filter paths of the first RF filter structure 60 are independent of one another. As such, the first tunable RF filter path 66 and the second tunable RF filter path 68 are independent of one another and thus do not have cross-coupling capacitive structures C between their resonators. Thus, in this embodiment, the cross-coupling capacitive structures C do not connect any of the weakly coupled resonators R(1,1), R(1,2) through (R(1,N) to any of the weakly coupled resonators R(M,1), R(M,2) through (R(M,N). This provides increased isolation between the first tunable RF filter path 66 and the second tunable RF filter path 68. In general, energy transfer between two weakly coupled resonators R in the first tunable RF filter path 66 and the second tunable RF filter path 68 may be provided by multiple energy transfer components. For example, energy may be transferred between the resonators R only through mutual magnetic coupling, only through mutual electric coupling, or through both mutual electric coupling and mutual magnetic coupling. Ideally, all of the mutual coupling coefficients are provided as designed, but in practice, the mutual coupling coefficients also be the result of parasitics. The inductors of the resonators R may also have magnetic coupling between them. A total coupling between the resonators R is given by the sum of magnetic and electric coupling.

In order to provide the transfer functions of the tunable RF filter paths 66, 68 with high out-of-band attenuation and a relatively low filter order, the tunable RF filter paths 66, 68 are configured to adjust notches in the transfer function, which are provided by the resonators R within the tunable RF filter paths 66, 68. The notches can be provided using parallel tanks connected in series or in shunt along a signal path of the first tunable RF filter path 66. To provide the notches, the parallel tanks operate approximately as an open circuit or as short circuits at certain frequencies. The notches can also be provided using multi-signal path cancellation. In this case, the tunable RF filter paths 66, 68 may be smaller and/or have fewer inductors. To tune the total mutual coupling coefficients between the resonators R towards a desired value, the tunable RF filter paths 66, 68 are configured to vary variable electric coupling coefficients so that parasitic couplings between the resonators R in the tunable RF filter paths 66, 68 are absorbed into a desired frequency transfer function.

FIG. 22 illustrates an exemplary embodiment of the first tunable RF filter path 66 in the first RF filter structure 60 shown in FIG. 21. While the exemplary embodiment shown in FIG. 22 is of the first tunable RF filter path 66, any of the tunable RF filter paths shown in the first RF filter structure 60 of FIG. 21 may be arranged in accordance with the exemplary embodiment shown in FIG. 22. The first tunable RF filter path 66 shown in FIG. 22 includes an embodiment of the resonator R(1,1) and an embodiment of the resonator R(1,2). The resonator R(1,1) and the resonator R(1,2) are weakly coupled to one another. More specifically, the resonator R(1,1) includes an inductor 208 and a capacitive structure 210. The resonator R(1,2) includes an inductor 212, a capacitive structure 214, and a capacitive structure 216.

The resonator R(1,1) and the resonator R(1,2) are a pair of weakly coupled resonators. The resonator R(1,1) and the resonator R(1,2) are weakly coupled by providing the inductor 208 and the inductor 212 such that the inductor 208 and the inductor 212 are weakly magnetically coupled. Although the resonator R(1,1) and the resonator R(1,2) are weakly coupled, the inductor 212 has a maximum lateral width and a displacement between the inductor 208 and the inductor 212 is less than or equal to half the maximum lateral width of the inductor 212. As such, the inductor 208 and the inductor 212 are relatively close to one another. The displacement between the inductor 208 and the inductor 212 may be measured from a geometric centroid of the inductor 208 to a geometric centroid of the inductor 212. The maximum lateral width may be a maximum dimension of the inductor 212 along a plane defined by its largest winding. The weak coupling between the inductor 208 and the inductor 212 is obtained through topological techniques. For example, the inductor 208 and the inductor 212 may be fully or partially aligned, where winding(s) of the inductor 208 and winding(s) of the inductor 212 are configured to provide weak coupling through cancellation. Alternatively or additionally, a plane defining an orientation of the winding(s) of the inductor 208 and a plane defining an orientation of the winding(s) of the inductor 212 may be fully or partially orthogonal to one another. Some of the magnetic couplings between the resonators R can be unidirectional (passive or active). This can significantly improve isolation (e.g., transmit and receive isolation in duplexers).

To maximize the quality (Q) factor of the tunable RF filter paths 66 through 68, most of the total mutual coupling should be realized magnetically, and only fine-tuning is provided electrically. This also helps to reduce common-mode signal transfer in the differential resonators and thus keeps the Q factor high. While the magnetic coupling can be adjusted only statically, with a new layout design, the electric coupling can be tuned on the fly (after fabrication). The filter characteristics (e.g., bias network structure, resonator capacitance) can be adjusted based on given coupling coefficients to maximize filter performance.

To provide a tuning range to tune a transfer function of the first tunable RF filter path 66 and provide a fast roll-off from a low-frequency side to a high-frequency side of the transfer function, the first tunable RF filter path 66 is configured to change a sign of a total mutual coupling coefficient between the resonator R(1,1) and the resonator R(1,2). Accordingly, the first tunable RF filter path 66 includes a cross-coupling capacitive structure C(P1) and a cross-coupling capacitive structure C(N1). The cross-coupling capacitive structure C(P1) and the cross-coupling capacitive structure C(N1) are embodiments of the cross-coupling capacitive structures C described above with regard to FIG. 21. As shown in FIG. 22, the cross-coupling capacitive structure C(P1) is electrically connected between the resonator R(1,1) and the resonator R(1,2) so as to provide a positive coupling coefficient between the resonator R(1,1) and the resonator R(1,2). The cross-coupling capacitive structure C(P1) is a variable cross-coupling capacitive structure configured to vary the positive coupling coefficient provided between the resonator R(1,1) and the resonator R(1,2). The cross-coupling capacitive structure C(N1) is electrically connected between the resonator R(1,1) and the resonator R(1,2) so as to provide a negative coupling coefficient between the resonator R(1,1) and the resonator R(1,2). The cross-coupling capacitive structure C(N1) is a variable cross-coupling capacitive structure configured to vary the negative coupling coefficient provided between the resonator R(1,1) and the resonator R(1,2). The arrangement of the cross-coupling capacitive structure C(P1) and the cross-coupling capacitive structure C(N1) shown in FIG. 22 is a V-bridge structure. In alternative embodiments, some or all of the cross-coupling capacitive structures is fixed (not variable).

In the resonator R(1,1), the inductor 208 and the capacitive structure 210 are electrically connected in parallel. More specifically, the inductor 208 has an end 217 and an end 218, which are disposed opposite to one another. The ends 217, 218 are each electrically connected to the capacitive structure 210, which is grounded. Thus, the resonator R(1,1) is a single-ended resonator. On the other hand, the inductor 212 is electrically connected between the capacitive structure 214 and the capacitive structure 216. More specifically, the inductor 212 has an end 220 and an end 222, which are disposed opposite to one another. The end 220 is electrically connected to the capacitive structure 214 and the end 222 is electrically connected to the capacitive structure 216. Both the capacitive structure 214 and the capacitive structure 216 are grounded. Thus, the resonator R(1,2) is a differential resonator. In an alternative, an inductor with a center tap can be used. The tap can be connected to ground and only a single capacitive structure can be used. In yet another embodiment, both an inductor and a capacitive structure may have a center tap that is grounded. In still another embodiment, neither the inductor nor the capacitive structure may have a grounded center tap.

The inductor 208 is magnetically coupled to the inductor 212 such that an RF signal received at the end 217 of the inductor 208 with a voltage polarity (i.e., either a positive voltage polarity or a negative voltage polarity) results in a filtered RF signal being transmitted out the end 220 of the inductor 212 with the same voltage polarity. Also, the inductor 212 is magnetically coupled to the inductor 208 such that an RF signal received at the end 220 of the inductor 212 with a voltage polarity (i.e., either a positive voltage polarity or a negative voltage polarity) results in a filtered RF signal being transmitted out the end 217 of the inductor 208 with the same voltage polarity. This is indicated in FIG. 22 by the dot convention where a dot is placed at the end 217 of the inductor 208 and a dot is placed at the end 220 of the inductor 212. By using two independent and adjustable coupling coefficients (i.e., the positive coupling coefficient and the negative coupling coefficient) with the resonator R(1,2) (i.e., the differential resonator), the transfer function of the first tunable RF filter path 66 is provided so as to be fully adjustable. More specifically, the inductors 208, 212 may be magnetically coupled so as to have a low magnetic coupling coefficient through field cancellation, with the variable positive coupling coefficient and the variable negative coupling coefficient. In this case, the inductor 208 and the inductor 212 are arranged such that a mutual magnetic coupling between the inductor 208 and the inductor 212 cancel. Alternatively, the inductor 208 and the inductor 212 are arranged such that the inductor 212 reduces a mutual magnetic coupling coefficient of the inductor 208. With respect to the magnetic coupling coefficient, the variable positive coupling coefficient is a variable positive electric coupling coefficient and the variable negative coupling coefficient is a variable negative electric coupling coefficient. The variable positive electric coupling coefficient and the variable negative electric coupling coefficient oppose each other to create a tunable filter characteristic.

The resonator R(1,2) is operably associated with the resonator R(1,1) such that an energy transfer factor between the resonator R(1,1) and the resonator R(1,2) is less than 10%. A total mutual coupling between the resonator R(1,1) and the resonator R(1,2) is provided by a sum total of the mutual magnetic factor between the resonator R(1,1) and the resonator R(1,2) and the mutual electric coupling coefficients between the resonator R(1,1) and the resonator R(1,2). In this embodiment, the mutual magnetic coupling coefficient between the inductor 208 and the inductor 212 is a fixed mutual magnetic coupling coefficient. Although embodiments of the resonators R(1,1), R(1,2) may be provided so as to provide a variable magnetic coupling coefficient between the resonators R(1,1), R(1,2), embodiments of the resonators R(1,1), R(1,2) that provide variable magnetic couplings can be costly and difficult to realize. However, providing variable electric coupling coefficients (i.e., the variable positive electric coupling coefficient and the variable electric negative coupling coefficient) is easier and more economical. Thus, using the cross-coupling capacitive structure C(P1) and the cross-coupling capacitive structure C(N1) to provide the variable positive electric coupling coefficient and the variable electric negative coupling coefficient is an economical technique for providing a tunable filter characteristic between the resonators R(1,1), R(1,2). Furthermore, since the mutual magnetic coupling coefficient between the inductor 208 and the inductor 212 is fixed, the first tunable RF filter path 66 has lower insertion losses.

In the embodiment shown in FIG. 22, the inductor 208 and the 212 inductor are the same size. Alternatively, the inductor 208 and the inductor 212 may be different sizes. For example, the inductor 212 may be smaller than the inductor 208. By determining a distance between the inductor 208 and the inductor 212, the magnetic coupling coefficient between the inductor 208 and the inductor 212 can be set. With regard to the inductors 208, 212 shown in FIG. 22, the inductor 208 may be a folded inductor configured to generate a first confined magnetic field, while the inductor 212 may be a folded inductor configured to generate a second confined magnetic field. Magnetic field lines of the first confined magnetic field and of the second confined magnetic field that are external to the inductor 208 and inductor 212 are cancelled by opposing magnetic field lines in all directions. When the inductor 208 and the inductor 212 are folded inductors, the folded inductors can be stacked. This allows building the first tunable RF filter path 66 such that several inductors 208, 212 are stacked. Furthermore, this arrangement allows for a specially sized interconnect structure that electrically connects the inductors 208, 212 to the capacitive structure 210, the capacitive structure 214, the capacitive structure 216, the cross-coupling capacitive structure C(P1), and the cross-coupling capacitive structure C(N1). The specially sized interconnect increases the Q factor of the capacitive structure 210, the capacitive structure 214, the capacitive structure 216, the cross-coupling capacitive structure C(P1), and the cross-coupling capacitive structure C(N1), and allows for precise control of their variable capacitances. Weakly coupled filters can also be realized with planar field cancellation structures.

FIG. 23 illustrates an exemplary embodiment of the first tunable RF filter path 66 in the first RF filter structure 60 shown in FIG. 21. While the exemplary embodiment shown in FIG. 23 is of the first tunable RF filter path 66, any of the tunable RF filter paths shown in the first RF filter structure 60 of FIG. 21 may be arranged in accordance with the exemplary embodiment shown in FIG. 23. The first tunable RF filter path 66 shown in FIG. 23 includes an embodiment of the resonator R(1,1) and an embodiment of the resonator R(1,2). The resonator R(1,1) and the resonator R(1,2) are weakly coupled to one another. The embodiment of the resonator R(1,2) is the same as the embodiment of the resonator R(1,2) shown in FIG. 22. Thus, the resonator R(1,2) shown in FIG. 23 is a differential resonator that includes the inductor 212, the capacitive structure 214, and the capacitive structure 216. Additionally, like the embodiment of the resonator R(1,1) shown in FIG. 22, the embodiment of the resonator R(1,1) shown in FIG. 23 includes the inductor 208 and the capacitive structure 210. However, in this embodiment, the resonator R(1,1) shown in FIG. 23 is a differential resonator and further includes a capacitive structure 224. More specifically, the end 217 of the inductor 208 is electrically connected to the capacitive structure 210 and the end 218 of the inductor 208 is electrically connected to the capacitive structure 224. Both the capacitive structure 210 and the capacitive structure 224 are grounded. Like the capacitive structure 210, the capacitive structure 224 is also a variable capacitive structure, such as a programmable array of capacitors or a varactor. Alternatively, a center tap of an inductor may be grounded. In yet another embodiment, the inductor and a capacitive structure may be RF floating (a low-resistance connection to ground).

The resonator R(1,1) and the resonator R(1,2) are a pair of weakly coupled resonators. Like the first tunable RF filter path 66 shown in FIG. 22, the resonator R(1,1) and the resonator R(1,2) are weakly coupled by providing the inductor 208 and the inductor 212 such that the inductor 208 and the inductor 212 are weakly coupled. Thus, the inductor 208 and the inductor 212 may have a magnetic coupling coefficient that is less than or equal to approximately 0.3. Although the resonator R(1,1) and the resonator R(1,2) are weakly coupled, a displacement between the inductor 208 and the inductor 212 is less than or equal to half the maximum lateral width of the inductor 212. As such, the inductor 208 and the inductor 212 are relatively close to one another. The displacement between the inductor 208 and the inductor 212 may be measured from a geometric centroid of the inductor 208 to a geometric centroid of the inductor 212. The maximum lateral width may be a maximum dimension of the inductor 212 along a plane defined by its largest winding.

The weak coupling between the inductor 208 and the inductor 212 is obtained through topological techniques. For example, the inductor 208 and the inductor 212 may be fully or partially aligned, where winding(s) of the inductor 208 and winding(s) of the inductor 212 are configured to provide weak coupling through cancellation. Alternatively or additionally, a plane defining an orientation of the windings of the inductor 208 and a plane defining an orientation of the windings of the inductor 212 may be fully or partially orthogonal to one another.

The resonator R(1,2) is operably associated with the resonator R(1,1) such that an energy transfer factor between the resonator R(1,1) and the resonator R(1,2) is less than 10%. To provide a tuning range to tune a transfer function of the first tunable RF filter path 66 such to provide a fast roll-off from a low-frequency side to a high-frequency side requires changing a sign of the total mutual coupling coefficient between the resonator R(1,1) and the resonator R(1,2). Like the embodiment of the first tunable RF filter path 66 shown in FIG. 22, the first tunable RF filter path 66 shown in FIG. 23 includes the cross-coupling capacitive structure C(P1) and the cross-coupling capacitive structure C(N1). The cross-coupling capacitive structure C(P1) and the cross-coupling capacitive structure C(N1) are arranged in the same manner described above with respect to FIG. 22. However, in this embodiment, the first tunable RF filter path 66 shown in FIG. 23 also includes a cross-coupling capacitive structure C(P2) and a cross-coupling capacitive structure C(N2). The cross-coupling capacitive structure C(P2) and the cross-coupling capacitive structure C(N2) are also embodiments of the cross-coupling capacitive structures C described above with regard to FIG. 21.

As described above with respect to FIG. 22, the cross-coupling capacitive structure C(P1) is electrically connected between the resonator R(1,1) and the resonator R(1,2) so as to provide the positive coupling coefficient (i.e., the variable positive electric coupling coefficient) between the resonator R(1,1) and the resonator R(1,2). Also as described above with respect to FIG. 22, the cross-coupling capacitive structure C(N1) is electrically connected between the resonator R(1,1) and the resonator R(1,2) so as to provide the negative coupling coefficient (i.e., the variable negative electric coupling coefficient) between the resonator R(1,1) and the resonator R(1,2). With regard to the cross-coupling capacitive structure C(P2), the cross-coupling capacitive structure C(P2) is electrically connected between the resonator R(1,1) and the resonator R(1,2) so as to provide another positive coupling coefficient (i.e., another variable positive electric coupling coefficient) between the resonator R(1,1) and the resonator R(1,2). In this embodiment, the cross-coupling capacitive structure C(P2) is electrically connected between the end 218 of the inductor 208 and the end 222 of the inductor 212. The cross-coupling capacitive structure C(P2) is a variable cross-coupling capacitive structure configured to vary the other positive coupling coefficient (i.e., the other variable positive electric coupling coefficient) provided between the resonator R(1,1) and the resonator R(1,2). With regard to the cross-coupling capacitive structure C(N2), the cross-coupling capacitive structure C(N2) is electrically connected between the resonator R(1,1) and the resonator R(1,2) so as to provide another negative coupling coefficient (i.e., another variable negative electric coupling coefficient) between the resonator R(1,1) and the resonator R(1,2). In this embodiment, the cross-coupling capacitive structure C(N2) is electrically connected between the end 218 of the inductor 208 and the end 220 of the inductor 212. The cross-coupling capacitive structure C(N2) is a variable cross-coupling capacitive structure configured to vary the negative coupling coefficient (i.e., the other variable negative electric coupling coefficient) provided between the resonator R(1,1) and the resonator R(1,2). The arrangement of the cross-coupling capacitive structure C(P1), the cross-coupling capacitive structure C(N1), the cross-coupling capacitive structure C(P2), and the cross-coupling capacitive structure C(N2) shown in FIG. 23 is an X-bridge structure.

As shown in FIG. 23, the resonator R(1,2) is operably associated with the resonator R(1,1) such that an energy transfer factor between the resonator R(1,1) and the resonator R(1,2) is less than 10%. The total mutual coupling between the resonator R(1,1) and the resonator R(1,2) is provided by a sum total of the mutual magnetic factor between the resonator R(1,1) and the resonator R(1,2) and the mutual electric coupling coefficients between the resonator R(1,1) and the resonator R(1,2). Thus, in this embodiment, the total mutual coupling between the resonator R(1,1) and the resonator R(1,2) is provided by the sum total of the mutual magnetic coupling coefficient, the variable positive electric coupling coefficient provided by the cross-coupling capacitive structure C(P1), the variable negative electric coupling coefficient provided by the cross-coupling capacitive structure C(N1), the other variable positive electric coupling coefficient provided by the cross-coupling capacitive structure C(P2), and the other variable negative electric coupling coefficient provided by the cross-coupling capacitive structure C(N2).

FIG. 24 illustrates an exemplary embodiment of the first tunable RF filter path 66 in the first RF filter structure 60 shown in FIG. 21. While the exemplary embodiment shown in FIG. 24 is of the first tunable RF filter path 66, any of the tunable RF filter paths shown in the first RF filter structure 60 of FIG. 21 may be arranged in accordance with the exemplary embodiment shown in FIG. 24. The first tunable RF filter path 66 shown in FIG. 24 includes an embodiment of the resonator R(1,1) and an embodiment of the resonator R(1,2). The resonator R(1,1) and the resonator R(1,2) are weakly coupled to one another. The embodiment of the resonator R(1,1) is the same as the embodiment of the resonator R(1,1) shown in FIG. 22. Thus, the resonator R(1,1) shown in FIG. 24 is a single-ended resonator that includes the inductor 208 and the capacitive structure 210. Additionally, like the embodiment of the resonator R(1,2) shown in FIG. 22, the embodiment of the resonator R(1,2) shown in FIG. 24 includes the inductor 212 and the capacitive structure 214. However, in this embodiment, the resonator R(1,2) shown in FIG. 24 is a single-ended resonator. More specifically, the end 220 and the end 222 of the inductor 212 are each electrically connected to the capacitive structure 214, which is grounded.

The resonator R(1,1) and the resonator R(1,2) are a pair of weakly coupled resonators. Like the first tunable RF filter path 66 shown in FIG. 22, the resonator R(1,1) and the resonator R(1,2) are weakly coupled by providing the inductor 208 and the inductor 212 such that the inductor 208 and the inductor 212 are weakly coupled. Thus, the inductor 208 and the inductor 212 may have a magnetic coupling coefficient that is less than or equal to approximately 0.3. Although the resonator R(1,1) and the resonator R(1,2) are weakly coupled, the displacement between the inductor 208 and the inductor 212 is less than or equal to half the maximum lateral width of the inductor 212. As such, the inductor 208 and the inductor 212 are relatively close to one another. The displacement between the inductor 208 and the inductor 212 may be measured from the geometric centroid of the inductor 208 to the geometric centroid of the inductor 212. The maximum lateral width may be a maximum dimension of the inductor 212 along a plane defined by its largest winding. The weak coupling between the inductor 208 and the inductor 212 is obtained through topological techniques. For example, the inductor 208 and the inductor 212 may be fully or partially aligned, where winding(s) of the inductor 208 and winding(s) of the inductor 212 are configured to provide weak coupling through cancellation. Alternatively or additionally, a plane defining an orientation of the windings of the inductor 208 and a plane defining an orientation of the windings of the inductor 212 may be fully or partially orthogonal to one another.

The resonator R(1,2) is operably associated with the resonator R(1,1) such that an energy transfer factor between the resonator R(1,1) and the resonator R(1,2) is less than 10%. To provide a tuning range to tune a transfer function of the first tunable RF filter path 66 and provide a fast roll-off from a low-frequency side to a high-frequency side of the transfer function, the first tunable RF filter path 66 is configured to change a sign of a total mutual coupling coefficient between the resonator R(1,1) and the resonator R(1,2). However, in this embodiment, the first tunable RF filter path 66 shown in FIG. 24 only includes the cross-coupling capacitive structure C(P1), which is electrically connected between the end 217 of the inductor 208 and the end 220 of the inductor 212. As discussed above with respect to FIGS. 22 and 23, the cross-coupling capacitive structure C(P1) is a variable cross-coupling capacitive structure configured to vary the positive coupling coefficient (i.e., the variable positive electric coupling coefficient) provided between the resonator R(1,1) and the resonator R(1,2). Thus, in order to allow for the sign of the total mutual coupling coefficient between the resonator R(1,1) and the resonator R(1,2) to be changed, the inductor 208 and the inductor 212 are arranged so as to provide a fixed negative mutual magnetic coupling coefficient between the inductor 208 of the resonator R(1,1) and the inductor 212 of the resonator R(1,2). As such, varying the variable positive electric coupling coefficient allows for the sign of the total mutual coupling coefficient between the resonator R(1,1) and the resonator R(1,2) to be changed using only the cross-coupling capacitive structure C(P1).

As such, in this embodiment, the inductor 208 is magnetically coupled to the inductor 212 such that an RF signal received at the end 217 of the inductor 208 with a voltage polarity (i.e., either a positive voltage polarity or a negative voltage polarity) results in a filtered RF signal with the same voltage polarity being transmitted out the end 222 of the inductor 212. In addition, the inductor 212 is magnetically coupled to the inductor 208 such that an RF signal received at the end 222 of the inductor 212 with a voltage polarity (i.e., either a positive voltage polarity or a negative voltage polarity) results in a filtered RF signal with the same voltage polarity being transmitted out the end 217 of the inductor 208. This is indicated in FIG. 24 by the dot convention where a dot is placed at the end 217 of the inductor 208 and a dot is placed at the end 222 of the inductor 212. By using the fixed negative mutual magnetic coupling coefficient and the variable positive electric coupling coefficient, the transfer function of the first tunable RF filter path 66 is provided so to be fully adjustable. The arrangement of the cross-coupling capacitive structure C(P1) shown in FIG. 24 is a single positive bridge structure.

FIG. 25 illustrates another exemplary embodiment of the first tunable RF filter path 66 in the first RF filter structure 60 shown in FIG. 21. While the exemplary embodiment shown in FIG. 25 is of the first tunable RF filter path 66, any of the tunable RF filter paths shown in the first RF filter structure 60 of FIG. 21 may be arranged in accordance with the exemplary embodiment shown in FIG. 25. The first tunable RF filter path 66 shown in FIG. 25 includes an embodiment of the resonator R(1,1) and an embodiment of the resonator R(1,2). The resonator R(1,1) and the resonator R(1,2) are weakly coupled to one another. The embodiment of the resonator R(1,1) is the same as the embodiment of the resonator R(1,1) shown in FIG. 22. Thus, the resonator R(1,1) shown in FIG. 25 is a single-ended resonator that includes the inductor 208 and the capacitive structure 210, which are arranged in the same manner described above with respect to FIG. 22. Like the resonator R(1,2) shown in FIG. 24, the resonator R(1,2) shown in FIG. 25 is a single-ended resonator that includes the inductor 212 and the capacitive structure 214. However, the inductor 208 shown in FIG. 25 is magnetically coupled to the inductor 212 such that an RF signal received at the end 217 of the inductor 208 with a voltage polarity (i.e., either a positive voltage polarity or a negative voltage polarity) results in a filtered RF signal with the same voltage polarity being transmitted out the end 220 of the inductor 212. Also, the inductor 212 shown in FIG. 25 is magnetically coupled to the inductor 208 such that an RF signal received at the end 220 of the inductor 212 with a voltage polarity (i.e., either a positive voltage polarity or a negative voltage polarity) results in a filtered RF signal with the same voltage polarity being transmitted out the end 217 of the inductor 208. This is indicated in FIG. 25 by the dot convention where a dot is placed at the end 217 of the inductor 208 and a dot is placed at the end 220 of the inductor 212. In alternative embodiments, the resonator R(1,2) is a differential resonator. In yet another alternative embodiment, the resonator R(1,1) is a single-ended resonator while the resonator R(1,2) is a differential resonator.

The resonator R(1,1) and the resonator R(1,2) are a pair of weakly coupled resonators. Like the first tunable RF filter path 66 shown in FIG. 22, the resonator R(1,1) and the resonator R(1,2) are weakly coupled by providing the inductor 208 and the inductor 212 such that the inductor 208 and the inductor 212 are weakly coupled. Thus, the inductor 208 and the inductor 212 may have a fixed magnetic coupling coefficient that is less than or equal to approximately 0.3. Although the resonator R(1,1) and the resonator R(1,2) are weakly coupled, a displacement between the inductor 208 and the inductor 212 is less than or equal to half the maximum lateral width of the inductor 212. As such, the inductor 208 and the inductor 212 are relatively close to one another. The displacement between the inductor 208 and the inductor 212 may be measured from a geometric centroid of the inductor 208 to a geometric centroid of the inductor 212. The maximum lateral width may be a maximum dimension of the inductor 212 along a plane defined by its largest winding.

The weak coupling between the inductor 208 and the inductor 212 is obtained through topological techniques. For example, the inductor 208 and the inductor 212 may be fully or partially aligned, where winding(s) of the inductor 208 and winding(s) of the inductor 212 are configured to provide weak coupling through cancellation. Alternatively or additionally, a plane defining an orientation of the windings of the inductor 208 and a plane defining an orientation of the windings of the inductor 212 may be fully or partially orthogonal to one another.

The resonator R(1,2) is operably associated with the resonator R(1,1) such that an energy transfer factor between the resonator R(1,1) and the resonator R(1,2) is less than 10%. To provide a tuning range to tune the transfer function of the first tunable RF filter path 66 and to provide a fast roll-off from the low-frequency side to the high-frequency side of the transfer function, the first tunable RF filter path 66 is configured to change the sign of the total mutual coupling coefficient between the resonator R(1,1) and the resonator R(1,2). In this embodiment, the first tunable RF filter path 66 shown in FIG. 25 includes a cross-coupling capacitive structure C(PH1), a cross-coupling capacitive structure (CNH1), a cross-coupling capacitive structure C(I1), a cross-coupling capacitive structure C(PH2), and a cross-coupling capacitive structure C(NH2). The cross-coupling capacitive structure C(PH1), the cross-coupling capacitive structure (CNH1), the cross-coupling capacitive structure C(I1), the cross-coupling capacitive structure C(PH2), and the cross-coupling capacitive structure C(NH2) are also embodiments of the cross-coupling capacitive structures C described above with regard to FIG. 21.

The cross-coupling capacitive structure C(PH1) and the cross-coupling capacitive structure C(NH1) are arranged to form a first capacitive voltage divider. The first capacitive voltage divider is electrically connected to the resonator R(1,1). More specifically, the cross-coupling capacitive structure C(PH1) is electrically connected between the end 217 of the inductor 208 and a common connection node H1. The cross-coupling capacitive structure C(NH1) is electrically connected between the end 218 of the inductor 208 and the common connection node H1. Additionally, the cross-coupling capacitive structure C(PH2) and the cross-coupling capacitive structure C(NH2) are arranged to form a second capacitive voltage divider. The second capacitive voltage divider is electrically connected to the resonator R(1,2). More specifically, the cross-coupling capacitive structure C(PH2) is electrically connected between the end 220 of the inductor 212 and a common connection node H2. The cross-coupling capacitive structure C(NH2) is electrically connected between the end 222 of the inductor 212 and the common connection node H2. As shown in FIG. 25, the cross-coupling capacitive structure C(I1) is electrically connected between the first capacitive voltage divider and the second capacitive voltage divider. More specifically, the cross-coupling capacitive structure C(I1) is electrically connected between the common connection node H1 and the common connection node H2. The arrangement of the cross-coupling capacitive structure C(PH1), the cross-coupling capacitive structure C(NH1), the cross-coupling capacitive structure C(PH2), the cross-coupling capacitive structure C(NH2), and the cross-coupling capacitive structure C(I1) shown in FIG. 25 is an H-bridge structure. In an alternative H-bridge structure, the cross-coupling capacitive structure C(I1) is not provided and instead there is a short between the common connection node H1 and the common connection node H2. In addition, a center tap of the inductor 208 may be grounded and/or the common connection node H1 may be grounded. Finally, a high impedance to ground may be provided at the common connection node H1.

With regard to the first capacitive voltage divider, the cross-coupling capacitive structure C(PH1) is a variable cross-coupling capacitive structure configured to vary a first variable positive electric coupling coefficient provided between the resonator R(1,1) and the common connection node H1. The cross-coupling capacitive structure C(NH1) is a variable cross-coupling capacitive structure configured to vary a first variable negative electric coupling coefficient provided between the resonator R(1,1) and the common connection node H1. Thus, a mutual electric coupling coefficient of the resonator R(1,1) is approximately equal to the first variable positive electric coupling coefficient and the first variable negative electric coupling coefficient.

With regard to the second capacitive voltage divider, the cross-coupling capacitive structure C(PH2) is a variable cross-coupling capacitive structure configured to vary a second variable positive electric coupling coefficient provided between the resonator R(1,2) and the common connection node H2. The cross-coupling capacitive structure C(NH2) is a variable cross-coupling capacitive structure configured to vary a second variable negative electric coupling coefficient provided between the resonator R(1,2) and the common connection node H2. Thus, a mutual electric coupling coefficient of the resonator R(1,2) is approximately equal to the second variable positive electric coupling coefficient and the second variable negative electric coupling coefficient. Furthermore, the cross-coupling capacitive structure C(I1) is a variable cross-coupling capacitive structure configured to vary a first variable intermediate electric coupling coefficient provided between the common connection node H1 and the common connection node H2. The first tunable RF filter path 66 shown in FIG. 25 thus has a total mutual coupling coefficient between the resonator R(1,1) and the resonator R(1,2) equal to the sum total of the mutual magnetic coupling coefficient between the inductor 208 and the inductor 212, the mutual electric coupling coefficient of the resonator R(1,1), the mutual electric coupling coefficient of the resonator R(1,2), and the first variable intermediate electric coupling coefficient provided between the common connection node H1 and the common connection node H2. In alternative embodiments, cross-coupling capacitive structures with fixed capacitances are provided.

In one embodiment, the cross-coupling capacitive structure C(PH1), the cross-coupling capacitive structure C(NH1), the cross-coupling capacitive structure C(PH2), the cross-coupling capacitive structure C(NH2), and the cross-coupling capacitive structure C(I1) may each be provided as a varactor. However, the cross-coupling capacitive structure C(PH1), the cross-coupling capacitive structure C(NH1), the cross-coupling capacitive structure C(PH2), the cross-coupling capacitive structure C(NH2), and the cross-coupling capacitive structure C(I1) may each be provided as a programmable array of capacitors in order to reduce insertion losses and improve linearity. The cross-coupling capacitive structure C(PH1), the cross-coupling capacitive structure C(NH1), the cross-coupling capacitive structure C(PH2), the cross-coupling capacitive structure C(NH2), and the cross-coupling capacitive structure C(I1) can also be any combination of suitable variable cross-coupling capacitive structures, such as combinations of varactors and programmable arrays of capacitors. Although the H-bridge structure can provide good linearity and low insertion losses, the H-bridge structure can also suffer from common-mode signal transfer.

FIG. 26 illustrates yet another exemplary embodiment of the first tunable RF filter path 66 in the first RF filter structure 60 shown in FIG. 21. While the exemplary embodiment shown in FIG. 26 is of the first tunable RF filter path 66, any of the tunable RF filter paths shown in the first RF filter structure 60 of FIG. 21 may be arranged in accordance with the exemplary embodiment shown in FIG. 26. The first tunable RF filter path 66 shown in FIG. 26 can be used to ameliorate the common-mode signal transfer of the H-bridge structure shown in FIG. 25. More specifically, the first tunable RF filter path 66 shown in FIG. 26 includes the same embodiment of the resonator R(1,1) and the same embodiment of the resonator R(1,2) described above with respect to FIG. 25. Furthermore, the first tunable RF filter path 66 shown in FIG. 26 includes the first capacitive voltage divider with the cross-coupling capacitive structure C(PH1) and the cross-coupling capacitive structure C(NH1) described above with respect to FIG. 25, the second capacitive voltage divider with the cross-coupling capacitive structure C(PH2) and the cross-coupling capacitive structure (CNH2) described above with respect to FIG. 25, and the cross-coupling capacitive structure C(I1) described above with respect to FIG. 25. However, in this embodiment, the first tunable RF filter path 66 shown in FIG. 26 also includes a cross-coupling capacitive structure C(PH3), a cross-coupling capacitive structure (CNH3), a cross-coupling capacitive structure C(I2), a cross-coupling capacitive structure C(PH4), and a cross-coupling capacitive structure C(NH4). The cross-coupling capacitive structure C(PH3), the cross-coupling capacitive structure (CNH3), the cross-coupling capacitive structure C(I2), the cross-coupling capacitive structure C(PH4), and the cross-coupling capacitive structure C(NH4) are also embodiments of the cross-coupling capacitive structures C described above with regard to FIG. 21.

As shown in FIG. 26, the cross-coupling capacitive structure C(PH3) and the cross-coupling capacitive structure C(NH3) are arranged to form a third capacitive voltage divider. The third capacitive voltage divider is electrically connected to the resonator R(1,1). More specifically, the cross-coupling capacitive structure C(PH3) is electrically connected between the end 217 of the inductor 208 and a common connection node H3. The cross-coupling capacitive structure C(NH3) is electrically connected between the end 218 of the inductor 208 and the common connection node H3. Additionally, the cross-coupling capacitive structure C(PH4) and the cross-coupling capacitive structure C(NH4) are arranged to form a fourth capacitive voltage divider. The fourth capacitive voltage divider is electrically connected to the resonator R(1,2). More specifically, the cross-coupling capacitive structure C(PH4) is electrically connected between the end 220 of the inductor 212 and a common connection node H4. The cross-coupling capacitive structure C(NH4) is electrically connected between the end 222 of the inductor 212 and the common connection node H4. As shown in FIG. 26, the cross-coupling capacitive structure C(I2) is electrically connected between first capacitive voltage divider and the second capacitive voltage divider. More specifically, the cross-coupling capacitive structure C(I2) is electrically connected between the common connection node H3 and the common connection node H4. Alternatively, the cross-coupling capacitive structure C(I1) and the cross-coupling capacitive structure C(I2) can be replaced with shorts. The arrangement of the cross-coupling capacitive structure C(PH1), the cross-coupling capacitive structure C(NH1), the cross-coupling capacitive structure C(PH2), the cross-coupling capacitive structure C(NH2), the cross-coupling capacitive structure C(I1), the cross-coupling capacitive structure C(PH3), the cross-coupling capacitive structure C(NH3), the cross-coupling capacitive structure C(PH4), the cross-coupling capacitive structure C(NH4), and the cross-coupling capacitive structure C(I2) shown in FIG. 26 is a double H-bridge structure.

With regard to the third capacitive voltage divider, the cross-coupling capacitive structure C(PH3) is a variable cross-coupling capacitive structure configured to vary a third variable positive electric coupling coefficient provided between the resonator R(1,1) and the common connection node H3. The cross-coupling capacitive structure C(NH3) is a variable cross-coupling capacitive structure configured to vary a third variable negative electric coupling coefficient provided between the resonator R(1,1) and the common connection node H3. Thus, a mutual electric coupling coefficient of the resonator R(1,1) is approximately equal to the first variable positive electric coupling coefficient, the third variable positive electric coupling coefficient, the first variable negative electric coupling coefficient and the third variable negative electric coupling coefficient.

With regard to the fourth capacitive voltage divider, the cross-coupling capacitive structure C(PH4) is a variable cross-coupling capacitive structure configured to vary a fourth variable positive electric coupling coefficient provided between the resonator R(1,2) and the common connection node H4. The cross-coupling capacitive structure C(NH4) is a variable cross-coupling capacitive structure configured to vary a fourth variable negative electric coupling coefficient provided between the resonator R(1,2) and the common connection node H4. Thus, a mutual electric coupling coefficient of the resonator R(1,2) is approximately equal to the second variable positive electric coupling coefficient, the fourth variable positive coupling coefficient, the second variable negative coupling coefficient, and the fourth variable negative electric coupling coefficient. Furthermore, the cross-coupling capacitive structure C(I2) is a variable cross-coupling capacitive structure configured to vary a second variable intermediate electric coupling coefficient provided between the common connection node H3 and the common connection node H4. The first tunable RF filter path 66 shown in FIG. 26 thus has a total mutual coupling coefficient between the resonator R(1,1) and the resonator R(1,2) equal to the sum total of the mutual magnetic coupling coefficient between the inductor 208 and the inductor 212, the mutual electric coupling coefficient of the resonator R(1,1), the mutual electric coupling coefficient of the resonator R(1,2), the first variable intermediate electric coupling coefficient provided between the common connection node H1 and the common connection node H2 and the second variable intermediate electric coupling coefficient provided between the common connection node H3 and the common connection node H4. The double H-bridge structure thus includes two H-bridge structures. The two H-bridge structures allow for common-mode signal transfers of the two H-bridge structures to oppose one another and thereby be reduced and even cancelled.

FIG. 27 illustrates still another exemplary embodiment of the first tunable RF filter path 66 in the first RF filter structure 60 shown in FIG. 21. While the exemplary embodiment shown in FIG. 27 is of the first tunable RF filter path 66, any of the tunable RF filter paths shown in the first RF filter structure 60 of FIG. 21 may be arranged in accordance with the exemplary embodiment shown in FIG. 27. The first tunable RF filter path 66 shown in FIG. 27 includes the same embodiment of the resonator R(1,1) and the same embodiment of the resonator R(1,2) described above with respect to FIG. 22. In addition, the first tunable RF filter path 66 shown in FIG. 27 includes the cross-coupling capacitive structure C(P1) and the cross-coupling capacitive structure (CN1) that form the V-bridge structure described above with respect to FIG. 22. However, the first tunable RF filter path 66 shown in FIG. 27 further includes a resonator R(1,3) and a resonator R(1,4). More specifically, the resonator R(1,3) includes an inductor 226, a capacitive structure 228, and a capacitive structure 230. The resonator R(1,4) includes an inductor 232 and a capacitive structure 234.

With regard to the resonator R(1,3), the inductor 226 is electrically connected between the capacitive structure 228 and the capacitive structure 230. More specifically, the inductor 226 has an end 236 and an end 238, which are disposed opposite to one another. The end 236 is electrically connected to the capacitive structure 228 and the end 238 is electrically connected to the capacitive structure 230. Both the capacitive structure 228 and the capacitive structure 230 are grounded. Thus, the resonator R(1,3) is a differential resonator. In this embodiment, each of the capacitive structure 228 and the capacitive structure 230 is a variable capacitive structure.

With regard to the resonator R(1,4), the inductor 232 and the capacitive structure 234 are electrically connected in parallel. More specifically, the inductor 232 has an end 240 and an end 242, which are disposed opposite to one another. The ends 240, 242 are each electrically connected to the capacitive structure 234, which is grounded. Thus, the resonator R(1,4) is a single-ended resonator.

In this embodiment, the resonator R(1,1), the resonator R(1,2), the resonator R(1,3), and the resonator R(1,4) are all weakly coupled to one another. The resonator R(1,3) and the resonator R(1,4) are weakly coupled by providing the inductor 226 and the inductor 232 such that the inductor 226 and the inductor 232 are weakly coupled. The resonators R(1,1), R(1,2), R(1,3), and R(1,4) are each operably associated with one another such that energy transfer factors between the resonators R(1,1), R(1,2), R(1,3), and R(1,4) are less than 10%. Although the resonator R(1,3) and the resonator R(1,4) are weakly coupled, the inductor 232 has a maximum lateral width and a displacement between the inductor 226 and the inductor 232 is less than or equal to half the maximum lateral width of the inductor 232. As such, the inductor 226 and the inductor 232 are relatively close to one another. The displacement between the inductor 226 and the inductor 232 may be measured from a geometric centroid of the inductor 226 to a geometric centroid of the inductor 232. The maximum lateral width may be a maximum dimension of the inductor 232 along a plane defined by its largest winding. The weak coupling between the inductor 226 and the inductor 232 is obtained through topological techniques. For example, the inductor 226 and the inductor 232 may be fully or partially aligned, where winding(s) of the inductor 226 and winding(s) of the inductor 232 are configured to provide weak coupling through cancellation. Alternatively or additionally, a plane defining an orientation of the windings of the inductor 226 and a plane defining an orientation of the windings of the inductor 232 may be fully or partially orthogonal to one another.

In some embodiments, all of the inductors 208, 212, 226, 232 are provided such that displacements between each of the inductors 208, 212, 226, 232 are less than or equal to half the maximum lateral width of the inductor 212. Alternatively, in other embodiments, only a proper subset of the inductors 208, 212, 226, 232 has displacements that are less than or equal to half the maximum lateral width of the inductor 212. For example, while the displacement between the inductor 208 and the inductor 212 may be less than or equal to half the maximum lateral width of the inductor 212 and the displacement between the inductor 226 and the inductor 232 may be less than or equal to half the maximum lateral width of the inductor 232, the displacements from the inductor 208 and the inductor 212 to the inductor 226 and the inductor 232 may each be greater than half the maximum lateral width of the inductor 212 and half the maximum lateral width of the inductor 232.

The inductors 208, 212, 226, and 232 are magnetically coupled to the each other such that an RF signal received at the end 217 of the inductor 208 with a voltage polarity (i.e., either a positive voltage polarity or a negative voltage polarity) results in filtered RF signals with the same voltage polarity being transmitted out the end 220 of the inductor 212, the end 236 of the inductor 226, and the end 240 of the inductor 232. Also, the inductors 208, 212, 226, and 232 are magnetically coupled to the each other such that an RF signal received at the end 240 of the inductor 232 with a voltage polarity (i.e., either a positive voltage polarity or a negative voltage polarity) results in filtered RF signals with the same voltage polarity being transmitted out the end 217 of the inductor 208, the end 220 of the inductor 212, and the end 236 of the inductor 226. This is indicated in FIG. 27 by the dot convention where a dot is placed at the end 217 of the inductor 208, a dot is placed at the end 220 of the inductor 212, a dot is placed at the end 236 of the inductor 226, and a dot is placed at the end 240 of the inductor 232.

The first tunable RF filter path 66 shown in FIG. 27 includes a cross-coupling capacitive structure C(P3), a cross-coupling capacitive structure C(N3), a cross-coupling capacitive structure C(P4), and a cross-coupling capacitive structure C(N4) electrically connected between the resonator R(1,2) and the resonator R(1,3). With respect to the resonator R(1,2) and the resonator R(1,3), the cross-coupling capacitive structure C(P3), the cross-coupling capacitive structure C(N3), the cross-coupling capacitive structure C(P4) and the cross-coupling capacitive structure C(N4) are arranged to have the X-bridge structure described above with respect to FIG. 23. Thus, the cross-coupling capacitive structure C(P3) is electrically connected between the end 220 and the end 236 so as to provide a variable positive electric coupling coefficient between the resonator R(1,2) and the resonator R(1,3). The cross-coupling capacitive structure C(P3) is a variable cross-coupling capacitive structure configured to vary the variable positive electric coupling coefficient provided between the resonator R(1,2) and the resonator R(1,3). Also, the cross-coupling capacitive structure C(N3) is electrically connected between the end 220 and the end 238 so as to provide a variable negative electric coupling coefficient between the resonator R(1,2) and the resonator R(1,3). The cross-coupling capacitive structure C(N3) is a variable cross-coupling capacitive structure configured to vary the variable negative electric coupling coefficient provided between the resonator R(1,2) and the resonator R(1,3).

Additionally, the cross-coupling capacitive structure C(P4) is electrically connected between the end 222 and the end 238 so as to provide another variable positive electric coupling coefficient between the resonator R(1,2) and the resonator R(1,3). The cross-coupling capacitive structure C(P4) is a variable cross-coupling capacitive structure configured to vary the other variable positive electric coupling coefficient provided between the resonator R(1,2) and the resonator R(1,3). Finally, the cross-coupling capacitive structure C(N4) is electrically connected between the end 222 and the end 236 so as to provide another variable negative electric coupling coefficient between the resonator R(1,2) and the resonator R(1,3). The cross-coupling capacitive structure C(N4) is a variable cross-coupling capacitive structure configured to vary the other variable negative electric coupling coefficient provided between the resonator R(1,2) and the resonator R(1,3).

With respect to the resonator R(1,3) and the resonator R(1,4), the first tunable RF filter path 66 shown in FIG. 27 includes a cross-coupling capacitive structure C(P5) and a cross-coupling capacitive structure C(N5) electrically connected between the resonator R(1,3) and the resonator R(1,4). With respect to the resonator R(1,3) and the resonator R(1,4), the cross-coupling capacitive structure C(P5) and the cross-coupling capacitive structure C(N5) are arranged to have the V-bridge structure described above with respect to FIG. 22. Thus, the cross-coupling capacitive structure C(P5) is electrically connected between the end 236 and the end 240 so as to provide a variable positive electric coupling coefficient between the resonator R(1,3) and the resonator R(1,4). The cross-coupling capacitive structure C(P5) is a variable cross-coupling capacitive structure configured to vary the variable positive electric coupling coefficient provided between the resonator R(1,3) and the resonator R(1,4). Also, the cross-coupling capacitive structure C(N5) is electrically connected between the end 238 and the end 240 so as to provide a variable negative electric coupling coefficient between the resonator R(1,3) and the resonator R(1,4). The cross-coupling capacitive structure C(N5) is a variable cross-coupling capacitive structure configured to vary the variable negative electric coupling coefficient provided between the resonator R(1,3) and the resonator R(1,4).

The embodiment of first RF filter structure 60 shown in FIG. 27 also includes a cross-coupling capacitive structure C(P6), a cross-coupling capacitive structure C(N6), a cross-coupling capacitive structure C(P7), a cross-coupling capacitive structure C(N7), and a cross-coupling capacitive structure C(P8). With respect to the resonator R(1,1) and the resonator R(1,3), the cross-coupling capacitive structure C(P6) and the cross-coupling capacitive structure C(N6) are each electrically connected between the resonator R(1,1) and the resonator R(1,3). The cross-coupling capacitive structure C(P6) is electrically connected between the end 217 and the end 236 so as to provide a variable positive electric coupling coefficient between the resonator R(1,1) and the resonator R(1,3). The cross-coupling capacitive structure C(P6) is a variable cross-coupling capacitive structure configured to vary the variable positive electric coupling coefficient provided between the resonator R(1,1) and the resonator R(1,3). Also, the cross-coupling capacitive structure C(N6) is electrically connected between the end 217 and the end 238 so as to provide a variable negative electric coupling coefficient between the resonator R(1,1) and the resonator R(1,3). The cross-coupling capacitive structure C(N6) is a variable cross-coupling capacitive structure configured to vary the variable negative electric coupling coefficient provided between the resonator R(1,1) and the resonator R(1,3).

With respect to the resonator R(1,2) and the resonator R(1,4), the cross-coupling capacitive structure C(P7) and the cross-coupling capacitive structure C(N7) are each electrically connected between the resonator R(1,2) and the resonator R(1,4). The cross-coupling capacitive structure C(P7) is electrically connected between the end 220 and the end 240 so as to provide a variable positive electric coupling coefficient between the resonator R(1,2) and the resonator R(1,4). The cross-coupling capacitive structure C(P7) is a variable cross-coupling capacitive structure configured to vary the variable positive electric coupling coefficient provided between the resonator R(1,2) and the resonator R(1,4). Also, the cross-coupling capacitive structure C(N7) is electrically connected between the end 222 and the end 240 so as to provide a variable negative electric coupling coefficient between the resonator R(1,2) and the resonator R(1,4). The cross-coupling capacitive structure C(N7) is a variable cross-coupling capacitive structure configured to vary the variable negative electric coupling coefficient provided between the resonator R(1,2) and the resonator R(1,4).

With respect to the resonator R(1,1) and the resonator R(1,4), the cross-coupling capacitive structure C(P8) is electrically connected between the resonator R(1,1) and the resonator R(1,4). The cross-coupling capacitive structure C(P8) is electrically connected between the end 217 and the end 240 so as to provide a variable positive electric coupling coefficient between the resonator R(1,1) and the resonator R(1,4). The cross-coupling capacitive structure C(P8) is a variable cross-coupling capacitive structure configured to vary the variable positive electric coupling coefficient provided between the resonator R(1,1) and the resonator R(1,4).

Furthermore, in this embodiment, a variable capacitive structure 244 is electrically connected in series between the terminal 200 and the resonator R(1,1). The variable capacitive structure 244 is configured to vary a variable impedance of the first tunable RF filter path 66 as measured into the terminal 200 in order to match a source or a load impedance at the terminal 200. In addition, a variable capacitive structure 245 is electrically connected in series between the resonator R(1,4) and the terminal 202. The variable capacitive structure 245 is configured to vary a variable impedance of the first tunable RF filter path 66 as seen into the terminal 202 in order to match a source or a load impedance at the terminal 202.

FIGS. 28A through 28D illustrate different embodiments of the first RF filter structure 60, wherein each of the embodiments has different combinations of input terminals and output terminals. The first RF filter structure 60 can have various topologies. For example, the embodiment of the first RF filter structure 60 shown in FIG. 28A has a single input terminal IN and an integer number i of output terminals OUT₁-OUT_(i). As will be discussed below, the first RF filter structure 60 may define various tunable RF filter paths (e.g., the first tunable RF filter path 66, the second tunable RF filter path 68, the third tunable RF filter path 110, the fourth tunable RF filter path 112, the fifth tunable RF filter path 122, and the sixth tunable RF filter path 124 shown in FIGS. 4, 8, 11, 12, and 14-20) that may be used to receive different RF signals at the input terminal IN and transmit a different filtered RF signal from each of the output terminals OUT₁-OUT_(i). As such, the first RF filter structure 60 shown in FIG. 28A may be specifically configured to provide Single Input Multiple Output (SIMO) operations.

With regard to the embodiment of the first RF filter structure 60 shown in FIG. 28B, the first RF filter structure 60 has an integer number j of input terminals IN₁-IN_(j) and a single output terminal OUT. As will be discussed below, the first RF filter structure 60 may define various tunable RF filter paths (e.g., the first tunable RF filter path 66, the second tunable RF filter path 68, the third tunable RF filter path 110, the fourth tunable RF filter path 112, the fifth tunable RF filter path 122, and the sixth tunable RF filter path 124 shown in FIGS. 4, 8, 11, 12, and 14-20) that may be used to receive a different RF signal at each of the input terminals IN₁-IN_(j) and transmit different filtered RF signals from the single output terminal OUT. As such, the first RF filter structure 60 shown in FIG. 28B may be specifically configured to provide Multiple Input Single Output (MISO) operations.

With regard to the embodiment of the first RF filter structure 60 shown in FIG. 28C, the first RF filter structure 60 has a single input terminal IN and a single output terminal OUT. As will be discussed below, the first RF filter structure 60 may define various tunable RF filter paths (e.g., the first tunable RF filter path 66, the second tunable RF filter path 68, the third tunable RF filter path 110, the fourth tunable RF filter path 112, the fifth tunable RF filter path 122, and the sixth tunable RF filter path 124 shown in FIGS. 4, 8, 11, 12, and 14-20) that may be used to receive different RF signals at the single input terminal IN and transmit different filtered RF signals from the output terminal OUT. As such, the first RF filter structure 60 shown in FIG. 28A may be specifically configured to provide Single Input Single Output (SISO) operations.

With regard to the embodiment of the first RF filter structure 60 shown in FIG. 28D, the first RF filter structure 60 has the input terminals IN₁-IN_(j) and the output terminals OUT₁-OUT_(i). As will be discussed below, the first RF filter structure 60 may define various tunable RF filter paths (e.g., the first tunable RF filter path 66, the second tunable RF filter path 68, the third tunable RF filter path 110, the fourth tunable RF filter path 112, the fifth tunable RF filter path 122, and the sixth tunable RF filter path 124 shown in FIGS. 4, 8, 11, 12, and 14-20) that may be used to receive a different RF signal at each of the input terminal IN₁-IN_(j) and transmit a different filtered RF signal from each of the output terminals OUT₁-OUT_(i).

FIG. 29 illustrates another embodiment of the first RF filter structure 60. The first RF filter structure 60 shown in FIG. 29 includes one embodiment of the first tunable RF filter path 66 and one embodiment of the second tunable RF filter path 68. The first tunable RF filter path 66 includes the resonator R(1,1) and the resonator R(1,2). The resonator R(1,1) and the resonator R(1,2) are thus a first pair of weakly coupled resonators in the first tunable RF filter path 66. The second tunable RF filter path 68 includes the resonator R(2,1) and the resonator R(2,2). The resonator R(2,1) and the resonator R(2,2) are thus a second pair of weakly coupled resonators in the second tunable RF filter path 68.

As explained in further detail below, a set S of cross-coupling capacitive structures is electrically connected between the resonator R(1,1), the resonator R(1,2), the resonator R(2,1), and the resonator R(2,2) in the first tunable RF filter path 66 and the second tunable RF filter path 68. More specifically, the set S includes a cross-coupling capacitive structure C(PM1), a cross-coupling capacitive structure C(PM2), a cross-coupling capacitive structure C(PM3), a cross-coupling capacitive structure C(PM4), a cross-coupling capacitive structure C(NM1), and a cross-coupling capacitive structure C(NM2). The set S of cross-coupling capacitive structures interconnects the resonator R(1,1), the resonator R(1,2), the resonator R(2,1), and the resonator R(2,2) so that the first RF filter structure 60 shown in FIG. 29 is a matrix (in this embodiment, a 2×2 matrix) of the resonators R. In alternative embodiments, some of the cross-coupling capacitive structures C(PM1), C(PM2), C(PM3), C(PM4), C(NM1), and C(NM2) may be omitted depending on the filter transfer function to be provided.

Unlike in the embodiment of the first RF filter structure 60 shown in FIG. 21, in this embodiment, the first tunable RF filter path 66 and the second tunable RF filter path 68 are not independent of one another. The set S of cross-coupling capacitive structures thus provides for additional tunable RF filter paths to be formed from the resonator R(1,1), the resonator R(1,2), the resonator R(2,1), and the resonator R(2,2). As discussed in further detail below, the arrangement of the first RF filter structure 60 shown in FIG. 29 can be used to realize examples of each of the embodiments of the first RF filter structure 60 shown in FIGS. 28A-28D.

The cross-coupling capacitive structure C(PM1) is electrically connected within the first tunable RF filter path 66, while the cross-coupling capacitive structure C(PM4) is electrically connected within the second tunable RF filter path 68. More specifically, the cross-coupling capacitive structure C(PM1) is electrically connected between the resonator R(1,1) and the resonator R(1,2) in the first tunable RF filter path 66. The cross-coupling capacitive structure C(PM1) is a variable cross-coupling capacitive structure configured to provide and vary a (e.g., positive or negative) electric coupling coefficient between the resonator R(1,1) and the resonator R(1,2). The cross-coupling capacitive structure C(PM4) is a variable cross-coupling capacitive structure configured to provide and vary a (e.g., positive or negative) electric coupling coefficient between the resonator R(2,1) and the resonator R(2,2) in the second tunable RF filter path 68.

To provide additional tunable RF filter paths, the cross-coupling capacitive structure C(PM2), the cross-coupling capacitive structure C(PM3), the cross-coupling capacitive structure C(NM1), and the cross-coupling capacitive structure C(NM2) are each electrically connected between the first tunable RF filter path 66 and the second tunable RF filter path 68. The cross-coupling capacitive structure C(PM2) is a variable cross-coupling capacitive structure configured to provide and vary a (e.g., positive or negative) electric coupling coefficient between the resonator R(1,2) and the resonator R(2,2). The cross-coupling capacitive structure C(PM3) is a variable cross-coupling capacitive structure configured to provide and vary a (e.g., positive or negative) electric coupling coefficient between the resonator R(1,1) and the resonator R(2,1). The cross-coupling capacitive structure C(NM1) is a variable cross-coupling capacitive structure configured to provide and vary a (e.g., positive or negative) electric coupling coefficient between the resonator R(1,1) and the resonator R(2,2). The cross-coupling capacitive structure C(NM2) is a variable cross-coupling capacitive structure configured to provide and vary a (e.g., positive or negative) electric coupling coefficient between the resonator R(1,2) and the resonator R(2,1).

The first tunable RF filter path 66 is electrically connected between the input terminal IN₁ and the output terminal OUT₁. In addition, the second tunable RF filter path 68 is electrically connected between an input terminal IN₂ and an output terminal OUT₂. Accordingly, the first RF filter structure 60 shown in FIG. 29 is an embodiment of the first RF filter structure 60 shown in FIG. 28D. However, the input terminal IN₂ and the output terminal OUT₁ are optional and may be excluded in other embodiments. For example, if the input terminal IN₂ were not provided, but the output terminal OUT₁ and the output terminal OUT₂ were provided, the first RF filter structure 60 shown in FIG. 29 would be provided as an embodiment of the first RF filter structure 60 shown in FIG. 28A. It might, for example, provide a diplexing or a duplexing function. Furthermore, more than two input terminals or output terminals can be provided. Some examples include embodiments of the first RF filter structure 60 used for triplexing, quadplexing, herplexing, and providing FDD and carrier aggregation.

The first tunable RF filter path 66 still provides a path between the input terminal IN₁ and the output terminal OUT₁. However, assuming that the input terminal IN₂ is not provided for SIMO operation, the cross-coupling capacitive structure C(NM1) is electrically connected between the first tunable RF filter path 66 and the second tunable RF filter path 68 to define a first additional tunable RF filter path between the input terminal IN₁ and the output terminal OUT₂. The first additional tunable RF filter path is thus provided by a portion of the first tunable RF filter path 66 and a portion of the second tunable RF filter path 68. More specifically, the first additional tunable RF filter path includes the resonator R(1,1) and the resonator R(2,2). The first additional tunable RF filter path also includes the cross-coupling capacitive structure C(NM1) that is electrically connected between the resonator R(1,1) and the resonator R(1,2). A second additional tunable RF filter path, a third additional tunable RF filter path, a fourth additional tunable RF filter path, and a fifth additional tunable RF filter path are also defined from the input terminal IN₁ to the output terminal OUT₂. The second additional tunable RF filter path includes the resonator R(1,1), the cross-coupling capacitive structure C(PM1), the resonator R(1,2), the cross-coupling capacitive C(PM2), and the resonator R(2,2). Additionally, the third additional tunable RF filter path includes the resonator R(1,1), the cross-coupling capacitive structure C(PM3), the resonator R(2,1), the cross-coupling capacitive C(PM4), and the resonator R(2,2). The fourth additional tunable RF filter path includes the resonator R(1,1), the cross-coupling capacitive structure C(PM1), the resonator R(1,2), the cross-coupling capacitive C(NM2), the resonator R(2,1), the cross-coupling capacitive structure C(PM4), and the resonator R(2,2). Finally, the fifth additional tunable RF filter path includes the resonator R(1,1), the cross-coupling capacitive structure C(PM3), the resonator R(2,1), the cross-coupling capacitive C(NM2), the resonator R(1,2), the cross-coupling capacitive structure C(PM2), and the resonator R(2,2).

If the output terminal OUT₁ were not provided, but the input terminal IN₁ and the input terminal IN₂ were provided, the first RF filter structure 60 shown in FIG. 29 would be provided as an embodiment of the first RF filter structure 60 shown in FIG. 28B. In this case, the second tunable RF filter path 68 still provides a path between the input terminal IN₂ and the output terminal OUT₂. However, assuming that the output terminal OUT₁ is not provided for MISO operation, the first additional tunable RF filter path, the second additional tunable RF filter path, the third additional tunable RF filter path, the fourth additional tunable RF filter path, and the fifth additional tunable RF filter path would provide the paths from the input terminal IN₁ to the output terminal OUT₂.

Finally, if the input terminal IN₂ and the output terminal OUT₂ were not provided, the first RF filter structure 60 shown in FIG. 29 would be provided as an embodiment of the first RF filter structure 60 shown in FIG. 28C. In this case, the second tunable RF filter path 68 still provides a path between the input terminal IN₂ and the output terminal OUT₂. However, assuming that the output terminal IN₁ is not provided for MISO operation, the first additional tunable RF filter path, the second additional tunable RF filter path, the third additional tunable RF filter path, the fourth additional tunable RF filter path, and the fifth additional tunable RF filter path would provide the paths from the input terminal IN₁ to the output terminal OUT₂. This may constitute a SISO filter implemented with an array to allow for a large number of signal paths and thus create one or more notches in the transfer function.

With regard to the resonators R(1,1), R(1,2), R(2,1), R(2,2) shown in FIG. 29, the resonators R(1,1), R(1,2), R(2,1), R(2,2) may each be single-ended resonators, differential resonators, or different combinations of single-ended resonators and differential resonators. The resonator R(1,1) and the resonator R(1,2) in the first tunable RF filter path 66 may each be provided in accordance with any of the embodiments of the resonator R(1,1) and the resonator R(1,2) described above with respect to FIGS. 22-27. For example, the resonator R(1,1) may include the inductor 208 (see FIG. 24) and the capacitive structure 210 (see FIG. 24). The resonator R(1,2) may include the inductor 212 and the capacitive structure 214 (see FIG. 24). The resonator R(2,1) may include an inductor (like the inductor 208 in FIG. 24) and a capacitive structure (like the capacitive structure 210 shown in FIG. 24). The resonator R(2,2) may include an inductor (like the inductor 212 in FIG. 24) and a capacitive structure (like the capacitive structure 214 shown in FIG. 24).

Additionally, one or more of the resonators R(1,1), R(1,2) in the first tunable RF filter path 66 and one or more of the resonators R(2,1), R(2,2) in the second tunable RF filter path 68 may be weakly coupled. Thus, the resonators R(1,1), R(1,2), R(2,1), R(2,2) may be operably associated with one another such that an energy transfer factor between each of the resonators R(1,1), R(1,2), R(2,1), R(2,2) is less than 10%. Alternatively, the energy transfer factor between only a subset of the resonators R(1,1), R(1,2), R(2,1), R(2,2) is less than 10%. In addition, in at least some embodiments, not all of the resonators R(1,1), R(1,2), R(2,1), R(2,2) are weakly coupled to one another.

In this embodiment, the inductor 208 (see FIG. 24) of the resonator R(1,1), the inductor 212 (see FIG. 24) of the resonator R(1,2), the inductor of the resonator R(2,1), and the inductor of the resonator R(2,2) may all be weakly coupled to one another. In some embodiments, displacements between the inductor 208 (see FIG. 24) of the resonator R(1,1), the inductor 212 (see FIG. 24) of the resonator R(1,2), the inductor of the resonator R(2,1), and the inductor of the resonator R(2,2) may all be less than or equal to half the maximum lateral width of the inductor 212. Alternatively, in other embodiments, only a proper subset of the inductor 208 (see FIG. 24) of the resonator R(1,1), the inductor 212 (see FIG. 24) of the resonator R(1,2), the inductor of the resonator R(2,1), and the inductor of the resonator R(2,2) may have displacements that are less than or equal to half the maximum lateral width of the inductor 212.

FIG. 30 illustrates yet another embodiment of the first RF filter structure 60. The first RF filter structure 60 includes the resonators R described above with respect to FIG. 21. The resonators R of the first RF filter structure 60 shown in FIG. 30 are arranged as a two-dimensional matrix of the resonators R. In this embodiment, the first RF filter structure 60 includes an embodiment of the first tunable RF filter path 66, an embodiment of the second tunable RF filter path 68, an embodiment of the third tunable RF filter path 110, and an embodiment of the fourth tunable RF filter path 112. Thus, the integer M for the first RF filter structure 60 shown in FIG. 30 is four (4) or greater. Additionally, the integer N for the first RF filter structure 60 shown in FIG. 30 is 3 or greater. Note that in alternative embodiments, the integer M may be two (2) or greater and the integer N may be two (2) or greater. It should be noted that in alternative embodiments the number of resonators R in each row and column may be the same or different.

In the embodiment of the first RF filter structure 60 shown in FIG. 30, the first tunable RF filter path 66 includes the resonator R(1,1), the resonator R(1,2), and one or more additional resonators R, such as the resonator R(1,N), since the integer N is 3 or greater. All of the weakly coupled resonators R(1,1) through R(1,N) are weakly coupled to one another. Furthermore, the first tunable RF filter path 66 is electrically connected between a terminal TU1 and a terminal TANT1. With regard to the second tunable RF filter path 68, the second tunable RF filter path 68 includes the resonator R(2,1), the resonator R(2,2), and one or more additional resonators R, such as the resonator R(2,N), since the integer N is 3 or greater. All of the weakly coupled resonators R(2,1) through R(2,N) are weakly coupled to one another. Furthermore, the second tunable RF filter path 68 is electrically connected between a terminal TU2 and a terminal TANT2.

With regard to the third tunable RF filter path 110, the third tunable RF filter path 110 includes a resonator R(3,1), a resonator R(3,2), and one or more additional resonators R, such as a resonator R(3,N), since the integer N is 3 or greater. All of the weakly coupled resonators R(3,1) through R(3,N) are weakly coupled to one another. Alternatively, only a proper subset of them may be weakly coupled to one another. Furthermore, the third tunable RF filter path 110 is electrically connected between a terminal TU3 and a terminal TANT3. With regard to the fourth tunable RF filter path 112, the fourth tunable RF filter path 112 includes the resonator R(M,1), the resonator R(M,2), and one or more additional resonators R, such as the resonator R(M,N), since the integer N is 3 or greater. All of the weakly coupled resonators R(M,1) through R(M,N) are weakly coupled to one another. Alternatively, only a proper subset of them may be weakly coupled to one another. Furthermore, the fourth tunable RF filter path 112 is electrically connected between a terminal TU4 and a terminal TANT4.

The first tunable RF filter path 66 is configured to receive RF signals and output filtered RF signals. It should be noted that the first RF filter structure 60 may include any number of tunable RF filter paths, such as, for example, the third tunable RF filter path 110, the fourth tunable RF filter path 112, the fifth tunable RF filter path 122, and the sixth tunable RF filter path 124, described above with respect to FIGS. 11-14. Each of the resonators R may be a tunable resonator, which allows for a resonant frequency of each of the resonators to be varied to along a frequency range. In alternative embodiments, only a proper subset of the resonators R may be tunable. In still another embodiment, all of the resonators R are not tunable, but rather have a fixed transfer function.

In some embodiments, all of the resonators R in the first RF filter structure 60 shown in FIG. 30 are weakly coupled to one another. Thus, the resonators R may all be operably associated with one another such that energy transfer factors between the resonators R are less than 10%. Alternatively, the energy transfer factor is less than 10% only among a proper subset of the resonators R. In other embodiments, only the resonators R in adjacent tunable RF filter paths 66, 68, 110, 112 are weakly coupled to one another. For example, all the resonators R(1,1) through R(1,N) may be weakly coupled to all the resonators R(2,1) through R(2,N). In still other embodiments, only subsets of adjacent resonators R may be weakly coupled to each other. For example, the resonators R(1,1), R(1,2) may be weakly coupled to the resonators R(2,1), R(2,2), while the resonators R(3,1), R(3,2) may be weakly coupled to the resonators R(M,1), R(M,2). These and other combinations would be apparent to one of ordinary skill in the art in light of this disclosure.

Sets S(1), S(2), S(3), S(4), S(5), and S(6) of cross-coupled capacitive structures are electrically connected between the resonators R. Each of the sets S(1), S(2), S(3), S(4), S(5), and S(6) is arranged like the set S of cross-coupled capacitive structures described above with respect to FIG. 29. For example, in one particular exemplary embodiment (e.g., when M=4 and N=3), the set S(1) of cross-coupled capacitive structures is electrically connected between the resonators R(1,1), R(1,2) in the first tunable RF filter path 66 and the resonators R(2,1), R(2,2) in the second tunable RF filter path 68. The set S(2) of cross-coupled capacitive structures is electrically connected between the resonators R(1,2), R(1,N) in the first tunable RF filter path 66 and the resonators R(2,2), R(2,N) in the second tunable RF filter path 68. The set S(3) of cross-coupled capacitive structures is electrically connected between the resonators R(2,1), R(2,2) in the second tunable RF filter path 68 and the resonators R(3,1), R(3,2) in the third tunable RF filter path 110. The set S(4) of cross-coupled capacitive structures is electrically connected between the resonators R(2,2), R(2,N) in the second tunable RF filter path 68 and the resonators R(3,2), R(3,N) in the third tunable RF filter path 110. The set S(5) of cross-coupled capacitive structures is electrically connected between the resonators R(3,1), R(3,2) in the third tunable RF filter path 110 and the resonators R(M,1), R(M,2) in the fourth tunable RF filter path 112. Finally, the set S(6) of cross-coupled capacitive structures is electrically connected between the resonators R(3,2), R(3,N) in the third tunable RF filter path 110 and the resonators R(M,2), R(M,N) in the fourth tunable RF filter path 112. Note that some cross-coupled capacitive structures in the sets S(1), S(2), S(3), S(4), S(5), and S(6) of cross-coupled capacitive structures for the resonators R in adjacent columns or in adjacent ones of the tunable RF filter paths 66, 68, 110, 112 overlap. This is because in the matrix of the resonators R, each of the resonators R is adjacent to multiple other ones of the resonators R. In another embodiment, the sets S(1), S(2), S(3), S(4), S(5), and S(6) of cross-coupled capacitive structures may be connected between non-adjacent resonators R. For example, there may be cross-coupled capacitive structures between resonators R that are more than one column or row apart.

FIG. 31 illustrates the embodiment of the first RF filter structure 60 shown in FIG. 30 electrically connected to the first RF antenna 16, the second RF antenna 32, a third RF antenna 246, and a fourth RF antenna 247. More specifically, the first tunable RF filter path 66 is electrically connected to the first RF antenna 16 at the terminal TANT1. The second tunable RF filter path 68 is electrically connected to the second RF antenna 32 at the terminal TANT2. The third tunable RF filter path 110 is electrically connected to the third RF antenna 246 at the terminal TANT3. The fourth tunable RF filter path 112 is electrically connected to the fourth RF antenna 247 at the terminal TANT4. With the sets S(1), S(2), S(3), S(4), S(5), and S(6) of cross-coupled capacitive structures, the first RF filter structure 60 shown in FIG. 31 forms an interconnected two-dimensional matrix of the resonators R. Thus, in addition to the first tunable RF filter path 66, the second tunable RF filter path 68, the third tunable RF filter path 110, and the fourth tunable RF filter path 112, the sets S(1), S(2), S(3), S(4), S(5), and S(6) of cross-coupled capacitive structures provide a multitude of additional tunable RF filter paths between the terminals TU1, TU2, TU3, TU4 and the terminals TANT1, TANT2, TANT3, TANT4. It should be noted that in alternative embodiments, the terminals TANT1, TANT2, TANT3, TANT4 may not be connected to antennas. Some antennas may be omitted depending on the functionality being realized.

By tuning the sets S(1), S(2), S(3), S(4), S(5), and S(6), the first RF filter structure 60 shown in FIG. 31 can be tuned so that any combination of the resonators R is selectable for the propagation of RF signals. More specifically, the first RF filter structure 60 shown in FIG. 31 is tunable to route RF receive signals from any combination of the terminals TANT1, TANT2, TANT3, TANT4 to any combination of the terminals TU1, TU2, TU3, TU4. Additionally, the first RF filter structure 60 shown in FIG. 31 is tunable to route RF transmission signals from any combination of the terminals TU1, TU2, TU3, TU4 to the terminals TANT1, TANT2, TANT3, TANT4. Accordingly, the first RF filter structure 60 can be configured to implement various MIMO, SIMO, MISO, and SISO operations.

FIG. 32 illustrates the first RF filter structure 60 shown in FIGS. 30 and 31 with examples of additional tunable RF filter paths 248, 250 highlighted. It should be noted, however, that there are a vast number of additional combinations of the resonators R that may be selected to provide tunable RF filter paths (e.g., the first tunable RF filter path 66, the second tunable RF filter path 68, the third tunable RF filter path 110, the fourth tunable RF filter path 112, the additional tunable RF filter path 248, and the additional tunable RF filter path 250) between the terminals TU1, TU2, TU3, TU4 and the terminals TANT1, TANT2, TANT3, TANT4. An explicit description of all of the various combinations of the resonators R that may be implemented with the first RF filter structure 60 shown in FIGS. 30-32 is simply impractical given the high number of possible combinations. Along with the previous descriptions, the additional tunable RF filter paths 248, 250 are highlighted in FIG. 32 simply to give examples of the basic concepts. However, the combinations provided for the additional tunable RF filter paths 248, 250 are in no way limiting, as any combination of the resonators R may be selected to route RF signals between the terminals TU1, TU2, TU3, TU4 and the terminals TANT1, TANT2, TANT3, TANT4. Any number of functions, such as signal combining, splitting, multiplexing, and demultiplexing, with various filtering profiles for each, may be realized.

With regard to the additional tunable RF filter paths 248, 250 highlighted in FIG. 32, the additional tunable RF filter paths 248, 250 may be used during MIMO, SIMO, MISO, and SISO operations. More specifically, the additional tunable RF filter path 248 connects the terminal TANT1 to the terminal TU2. The additional tunable RF filter path 250 connects the terminal TANT3 to the terminal TU2. As such, the first RF filter structure 60 may be tuned so that the additional tunable RF filter path 248 and the additional tunable RF filter path 250 are selected in a MISO operation from the terminal TANT1 and the terminal TANT3 to the terminal TU2. The additional tunable RF filter paths 248, 250 may also be used in SIMO operations. For example, the first RF filter structure 60 may be tuned so that the first tunable RF filter path 66 and the additional tunable RF filter path 248 are selected in a SIMO operation from the terminal TU2 to the terminal TANT1. The additional tunable RF filter paths 248, 250 can also be used in SISO operations from the terminal TANT1 to the terminal TU2 or from the terminal TANT3 to the terminal TU2. Finally, the additional tunable RF filter paths 248, 250 may also be used in SIMO operations. For instance, the first RF filter structure 60 may be tuned so that the first tunable RF filter path 66 and the additional tunable RF filter path 250 are selected in a SIMO operation from the terminal TANT1 to the terminal TU1 and from the terminal TANT3 to the terminal TU2.

In some applications involving the first RF filter structure 60 in FIGS. 30-32, MISO and SIMO operations can be used in conjunction with wideband antenna cables or fiber for transmitting RF signals in multiple RF communication frequency bands. Specific communication frequency bands can be processed by certain dedicated RF filtering paths in the first RF filter structure 60. For example, different RF signals may be injected from a wideband antenna and then propagated along different dedicated tunable RF filter paths in the first RF filter structure 60 to the terminals TU1, TU2, TU3, TU4. These dedicated tunable RF filter paths can be configured to have a transfer function that is specifically designed to handle these RF signals. Furthermore, the first RF filter structure 60 shown in FIGS. 30-32 is configured to tune a transfer function of any of the specific tunable RF filter paths (e.g., the first tunable RF filter path 66, the second tunable RF filter path 68, the third tunable RF filter path 110, the fourth tunable RF filter path 112, the additional tunable RF filter path 248, and the additional tunable RF filter path 250) in the first RF filter structure 60 by tuning resonators R that are not in the specific tunable RF filter path being used to route RF signals. This can help reduce out-of-band noise and reduce insertion losses. It can also improve isolation and out-of-band attenuation.

FIG. 33 illustrates yet another embodiment of the first RF filter structure 60. The first RF filter structure 60 includes the resonators R and is arranged as a two-dimensional matrix of the resonators R, where N is equal to four (4) and M is equal to three (3). In this embodiment, the first RF filter structure 60 includes an embodiment of the first tunable RF filter path 66, an embodiment of the second tunable RF filter path 68, and an embodiment of the third tunable RF filter path 110. It should be noted that in alternative embodiments, the number of resonators R in each row and column may be the same or different.

In the embodiment of the first RF filter structure 60 shown in FIG. 33, the first tunable RF filter path 66 includes the resonator R(1,1), the resonator R(1,2), the resonator R(1,3), and the resonator R(1,4). Furthermore, the first tunable RF filter path 66 is electrically connected between the terminal TU1 and the terminal TANT1. With regard to the second tunable RF filter path 68, the second tunable RF filter path 68 includes the resonator R(2,1), the resonator R(2,2), a resonator R(2,3), and a resonator R(2,4). Furthermore, the second tunable RF filter path 68 is electrically connected between the terminal TU2 and the terminal TANT2. With regard to the third tunable RF filter path 110, the third tunable RF filter path 110 includes the resonator R(3,1), the resonator R(3,2), a resonator R(3,3), and a resonator R(3,4). Furthermore, the third tunable RF filter path 110 is electrically connected between the terminal TU3 and the terminal TANT3.

In this embodiment, the resonators R in a subset 252 of the resonators R(1,1), R(1,2) in the first tunable RF filter path 66 are weakly coupled to one another. A cross-coupling capacitive structure CS1 is electrically connected between the resonators R(1,1), R(1,2). The cross-coupling capacitive structure CS1 is a variable cross-coupling capacitive structure configured to vary a variable electric coupling coefficient between the resonators R(1,1), R(1,2). A subset 254 of the resonators R(1,3), and R(1,4) in the second tunable RF filter path 68 is also weakly coupled to each other. A cross-coupling capacitive structure CS2 is electrically connected between the resonators R(1,3), R(1,4). The cross-coupling capacitive structure CS2 is a variable cross-coupling capacitive structure configured to vary a variable electric coupling coefficient between the resonators R(1,3), R(1,4).

As shown in FIG. 33, a unidirectional coupling stage 256 is electrically connected within the first tunable RF filter path 66. The unidirectional coupling stage 256 defines an amplifier gain and is configured to provide amplification within the first tunable RF filter path 66 in accordance with the amplifier gain. In some embodiments, the amplifier gain of the unidirectional coupling stage 256 is a variable amplifier gain. In this embodiment, the unidirectional coupling stage 256 is electrically connected between the resonator R(1,2) and the resonator R(1,3). The variable amplifier gain can thus control a variable electric coupling coefficient between the resonator R(1,2) in the subset 252 and the resonator R(1,3) in the subset 254. Since the unidirectional coupling stage 256 is an active semiconductor component, the unidirectional coupling stage 256 is unidirectional and thus only allows signal propagations from an input terminal IA of the unidirectional coupling stage 256 to an output terminal OA of the unidirectional coupling stage 256. Thus, the resonator R(1,2) in the subset 252 is unidirectionally mutual electrically coupled to the resonator R(1,3) in the subset 254.

Note that the resonators R(1,3), R(1,4) in the subset 254 are not electrically connected to the second tunable RF filter path 68 and the third tunable RF filter path 110. As such, the unidirectional coupling stage 256 thus results in a portion of the first tunable RF filter path 66 with the subset 254 of the resonators R(1,3), R(1,4) to be unidirectional. Consequently, signal flow can be to the terminal TANT1 but not from the terminal TANT1. Since the unidirectional coupling stage 256 is unidirectional, the variable amplifier gain (and thus the variable electric coupling coefficient between the resonator R(1,2) and the resonator R(1,3)) may be controlled using feed-forward control techniques and/or feedback control techniques.

Next, the resonators R in a subset 258 of the resonators R(2,1), R(2,2), R(3,1), and R(3,2) in the second tunable RF filter path 68 and in the third tunable RF filter path 110 are weakly coupled to one another. An unidirectional coupling stage 260 is electrically connected between the first tunable RF filter path 66 and the second tunable RF filter path 68. More specifically, the unidirectional coupling stage 260 is electrically connected between the resonator R(1,1) and the resonator R(2,1). The unidirectional coupling stage 260 defines an amplifier gain and is configured to provide amplification in accordance with the amplifier gain. In some embodiments, the amplifier gain of the unidirectional coupling stage 260 is a variable amplifier gain. The variable amplifier gain thus can control a variable electric coupling coefficient between the resonator R(1,1) in the subset 252 and the resonator R(2,1) in the subset 258. A cross-coupling capacitive structure CS3 is electrically connected between the resonator R(1,2) and the resonator R(2,2). The cross-coupling capacitive structure CS3 is a variable cross-coupling capacitive structure configured to vary a variable electric coupling coefficient between the resonators R(1,2), R(2,2).

To interconnect the resonators R(2,1), R(2,2), R(3,1), and R(3,2), a set S(A) of cross-coupling capacitive structures is electrically connected between the resonators R(2,1), R(2,2), R(3,1), and R(3,2) in the subset 258. The set S(A) of cross-coupling capacitive structures is arranged like the set S of cross-coupling capacitive structures described above with respect to FIG. 29. Additionally, the resonators R in a subset 262 of the resonators R(2,3), R(2,4), R(3,3), and R(3,4) in the second tunable RF filter path 68 and in the third tunable RF filter path 110 are weakly coupled to one another. A set S(B) of cross-coupling capacitive structures is electrically connected between the resonators R(2,3), R(2,4), R(3,3), and R(3,4) in the subset 262. The set S(B) of cross-coupling capacitive structures is arranged like the set S of cross-coupling capacitive structures described above with respect to FIG. 29.

To interconnect the subset 258 and the subset 262, the first RF filter structure 60 shown in FIG. 33 includes a cross-coupling capacitive structure CS4 and a unidirectional coupling stage 264. The cross-coupling capacitive structure CS4 is electrically connected between the resonators R(2,2), R(2,3). The cross-coupling capacitive structure CS4 is a variable cross-coupling capacitive structure configured to vary a variable electric coupling coefficient between the resonators R(2,2), R(2,3). The unidirectional coupling stage 264 is electrically connected within the third tunable RF filter path 110. In this embodiment, the unidirectional coupling stage 264 is electrically connected between the resonator R(3,3) and the resonator R(3,2). The unidirectional coupling stage 264 defines an amplifier gain and is configured to provide amplification within the third tunable RF filter path 110 in accordance with the amplifier gain. In some embodiments, the amplifier gain of the unidirectional coupling stage 264 is a variable amplifier gain. The variable amplifier gain can thus control a variable electric coupling coefficient between the resonator R(3,3) in the subset 262 and the resonator R(3,2) in the subset 258. Since the unidirectional coupling stage 264 is an active semiconductor component, the unidirectional coupling stage 264 is unidirectional and thus only allows signal propagations from an input terminal IB of the unidirectional coupling stage 264 to an output terminal OB of the unidirectional coupling stage 264. Thus, the resonator R(3,3) in the subset 262 is unidirectionally mutual electrically coupled to the resonator R(3,2) in the subset 258. Consequently, the third tunable RF filter path 110 shown in FIG. 33 is unidirectional if the signal flow is between the terminal TANT3 and the terminal TU3 though the third tunable RF filter path 110. As such signal flow between the terminal TANT3 and the terminal TU3 is provided only through the third tunable RF filter path 110, signal flow can only be from the terminal TANT3 to the terminal TU3, and not vice versa. In other cases, an additional tunable RF signal path (e.g., the additional RF terminal tunable RF signal path that includes the resonators R(3,1), R(2,2), R(2,3) and R(3,4)) can be tuned to provide bidirectional signal flow between the terminal TU3 and the terminal TANT3 through the cross-coupling capacitive structure CS4. The unidirectional coupling stages 256, 260, 264 may be active devices, such as amplifiers, diodes, transistors, networks of transistors, buffer stages, attenuation stages, and the like. The unidirectional coupling stages 256, 260, 264 can have gains higher than one (1), lower than one (1), or equal to one (1). Additionally, the unidirectional coupling stages 256, 260, 264 may be passive devices. The unidirectional coupling stages 256, 260, 264 may not be entirely or ideally unilateral, but may have some finite reverse coupling. In this case, the unidirectional coupling stages 256, 260, 264 may be predominately unilateral. One example in which the unidirectional coupling stages 256, 260, 264 may be used for multi-resonator applications and may improve isolation between certain parts, such as transmission ports and receive ports of a duplexer.

FIG. 34 illustrates yet another embodiment of the first RF filter structure 60. The first RF filter structure 60 shown in FIG. 34 is integrated into an IC package 266. The first RF filter structure 60 shown in FIG. 34 includes the resonators R and is arranged as a two-dimensional matrix of the resonators R, where N is equal to three (3) and M is equal to two (2). It should be noted that in alternative embodiments the number of resonators R in each row and column may be the same or different.

In this embodiment, the first RF filter structure 60 includes an embodiment of the first tunable RF filter path 66 and an embodiment of the second tunable RF filter path 68. The first tunable RF filter path 66 includes the resonator R(1,1), the resonator R(1,2), and the resonator R(1,3). The second tunable RF filter path 68 includes the resonator R(2,1), the resonator R(2,2), and the resonator R(2,3). A set S(X) of cross-coupling capacitive structures is electrically connected between the resonators R(1,1), R(1,2), R(2,1), and R(2,2). The set S(X) of cross-coupling capacitive structures is arranged like the set S of cross-coupling capacitive structures described above with respect to FIG. 29. A set S(Y) of cross-coupling capacitive structures is electrically connected between the resonators R(1,2), R(1,3), R(2,2), and R(2,3). The set S(Y) of cross-coupling capacitive structures is also arranged like the set S of cross-coupling capacitive structures described above with respect to FIG. 29.

As shown in FIG. 34, the IC package 266 houses a package substrate 268, a semiconductor die 270, and a semiconductor die 272. The semiconductor die 270 and the semiconductor die 272 are mounted on the package substrate 268. In this embodiment, the resonators R of the first RF filter structure 60 are formed by the package substrate 268. The set S(X) of cross-coupling capacitive structures is formed by the semiconductor die 270. On the other hand, the set S(Y) of cross-coupling capacitive structures is formed by the semiconductor die 272. Thus, the set S(X) of cross-coupling capacitive structures and the set S(Y) of cross-coupling capacitive structures are formed on multiple and separate semiconductor dies 270, 272. Using the multiple and separate semiconductor dies 270, 272 may be helpful in order to increase isolation. The multiple and separate semiconductor dies 270, 272 may have less area than the semiconductor die 268 shown in FIG. 34. As such, the embodiment shown in FIG. 35 may consume less die area.

FIG. 35 illustrates another embodiment of an IC package 266′ that houses the same embodiment of the first RF filter structure 60 described above with regard to FIG. 34. The IC package 266′ is the same as the IC package 266 shown in FIG. 34, except that the IC package 266′ only has a single semiconductor die 274. In this embodiment, both the set S(X) of cross-coupling capacitive structures and the set S(Y) of cross-coupling capacitive structures are formed by the semiconductor die 272. Thus, the IC package 266′ allows for a more compact arrangement than the IC package 266.

FIG. 36 illustrates yet another embodiment of the first RF filter structure 60. In this embodiment, the first RF filter structure 60 is arranged as a three-dimensional matrix of resonators R1, R2, R3. More specifically, a two-dimensional matrix of the resonators R1 is provided on a plane k, a two-dimensional array of the resonators R2 is provided on a plane m, and a two-dimensional array of the resonators R3 is provided on a plane n. Cross-coupling capacitive structures CC are electrically connected between the resonators R1, R2, R3 that are adjacent to one another in the same plane k,m,n and in the different planes k,m,n. The three-dimensional matrix of resonators R1, R2, R3 thus allows for more resonators to be cross-coupled to one another. This allows for the first RF filter structure 60 to provide greater numbers of tunable RF filter paths and allows for the first RF filter structure 60 to be tuned more accurately.

In general, having more tunable RF filter paths allows for the synthesis of a more complex transfer function with multiple notches for better blocker rejection. The number of resonators R1, R2, R3 in each of the planes k, n, m may be different or the same. The three-dimensional matrix of resonators can be used in MIMO, SIMO, MISO, and SISO applications.

FIG. 37 illustrates an exemplary RF device 300. For example, the RF device 300 may be or may include the embodiments of the first RF filter structure 60 shown in FIGS. 4, 7, 8, 11-21, 28A-28D, and 29-36. In this embodiment, the RF device 300 is integrated into one embodiment of an integrated circuit (IC) package 302 (e.g., the IC package 266 shown in FIG. 35 or the IC package 266′ shown in FIG. 36) that includes a semiconductor die 304 (e.g., the semiconductor die 270 shown in FIG. 34, the semiconductor die 272 shown in FIG. 34, and the semiconductor die 274 shown in FIG. 35) and a package board 306 (e.g., the package substrate 268 shown in FIGS. 34 and 35). The RF device 300 includes a resonator (e.g., the resonators R, R1, R2, and R3 described above in FIGS. 21-27 and FIGS. 29-36) that includes an inductor 308 (e.g., the inductor 208 illustrated in FIGS. 21-27, the inductor 212 illustrated in FIGS. 21-27, the inductor 226 illustrated in FIG. 27, and the inductor 232 illustrated in FIG. 27), a capacitive structure 310A (e.g., any or part of the capacitive structures 210, 214, 216, 224, 228, 230, 234, any or part of the cross-coupled capacitive structures C, C(P1), C(P2), C(P3), C(P4), C(P5), C(P6), C(P7), C(P8), C(N1), C(N2), C(N3), C(N4), C(N5), C(N6), C(N7), C(PH1), C(PH2), C(PH3), C(PH4), C(NH1), C(NH2), C(NH3), C(NH4), C(I1), C(I2), CS1, CS2, CS3, CS4, or any or part of the cross-coupled capacitive structures in the sets S, S(1), S(2), S(3), S(4), S(5), S(6), S(A), S(B), S(X), and S(Y) shown in FIGS. 21-27 and 29-36), and a capacitive structure 310B (e.g., any or part of the capacitive structures 210, 214, 216, 224, 228, 230, 234, any or part of the cross-coupled capacitive structures C, C(P1), C(P2), C(P3), C(P4), C(P5), C(P6), C(P7), C(P8), C(N1), C(N2), C(N3), C(N4), C(N5), C(N6), C(N7), C(PH1), C(PH2), C(PH3), C(PH4), C(NH1), C(NH2), C(NH3), C(NH4), C(I1), C(I2), CS1, CS2, CS3, CS4, or any or part of the cross-coupled capacitive structures in the sets S, S(1), S(2), S(3), S(4), S(5), S(6), S(A), S(B), S(X), and S(Y) shown in FIGS. 21-27 and 29-36). (It should be noted that the capacitive structures 310A, 310B are referred to generically as element 310).

The inductor 308 may be provided in the resonator (e.g., the resonators R, R1, R2, and R3 described with regard to FIGS. 21-27 and 29-36) and the capacitive structures 310A, 310B may be part of or may be electrically connected to the resonator (e.g., the resonators R, R1, R2, and R3 shown in FIGS. 21-27 and 29-36) and should have a high Q factor in order to optimize performance and reduce noise distortion. In many applications, however, the inductors (e.g., the inductor 308) and the capacitive structures (e.g. the capacitive structures 310A, 310B) used in or electrically connected to the resonators are provided on a combination of different electronic support architectures, such as semiconductor dies, package boards for IC packages, printed circuit boards (PCBs), or any combination of the like. For example, in the embodiment shown in FIG. 37, the inductor 308 may be formed by the package board 306 while the capacitive structures 310A, 310B are formed by the semiconductor die 304.

As explained in further detail below, the RF device 300 shown in FIG. 37 allows for interconnections between the inductor 308 in the package board 306, the capacitive structures 310A, 310B, and other components in the semiconductor die 304 without significantly degrading the high Q factor of the resonator. More specifically, the interconnections provided by the RF device 300 prevent or reduce current crowding, which significantly reduces a Q factor of components in RF devices (not shown) of previously known structures. While the interconnections provided here are provided with the inductor 308 formed by one electronic support architecture (e.g., the package board 306) and the capacitive structures 310 are formed by another electronic support architecture (e.g., the semiconductor die 304), the techniques described herein to provide interconnections are equally applicable when the interconnections need to be provided and the inductor 308 and the capacitive structures 310 are formed on a single electronic support architecture (e.g., a single multi-layered substrate). These and other applications would be apparent to one of ordinary skill in the art in light of this disclosure.

The inductor 308 has an inductor terminal 312A and an inductor terminal 312B. At the inductor terminals 312A, 312B, the inductor 308 is configured to receive and/or transmit a current 313. The current 313 is shown propagating from the inductor terminal 312A, through the capacitive structures 310A, 310B in the semiconductor die 304 and to the inductor terminal 312B. The semiconductor die 304 may include one or more active semiconductor devices (referred to generically as elements 314 and specifically as elements 314A-314N). The semiconductor die 304 includes N number of the active semiconductor devices 314, where N is an integer greater than or equal to one. In this embodiment, the active semiconductor devices 314 are a stack of field-effect transistors (FETs). However, each of the active semiconductor devices 314 may be any type of active semiconductor device, such as other types of transistors, diodes, metal-on-semiconductor (MOS) capacitive structures, varactors, on-chip resistive structures, metal-insulator-metal (MIM) capacitive structures, metal-on-metal capacitive structures, and/or the like. As shown in FIG. 37, the active semiconductor devices 314 include a device contact 316A and a device contact 316B. In this embodiment, the device contact 316A is a drain contact of the active semiconductor device 314A at a first end of the stack of FETs and the device contact 316B is a source contact of the active semiconductor device 314B at a second end of the stack of FETs opposite the first end. The active semiconductor devices 314 thus electrically connect the device contact 316A to the device contact 316B. In this manner, the active semiconductor devices 314 form a switch path between the device contact 316A and the device contact 316B.

As shown in FIG. 37, the device contact 316A is positioned so as to be vertically aligned directly below the inductor terminal 312A. Additionally, the device contact 316B is positioned so as to be vertically aligned directly below the inductor terminal 312B. To interconnect the inductor terminal 312A to the device contact 316A, the semiconductor die 304 includes an interconnection path 318A that electrically connects the inductor terminal 312A to the device contact 316A. The capacitive structure 310A is formed within the interconnection path 318A. Similarly, the semiconductor die 304 includes an interconnection path 318B that electrically connects the inductor terminal 312B to the device contact 316B to interconnect the inductor terminal 312B to the device contact 316B. Since the active semiconductor devices 314 are stacked, the active semiconductor devices 314 provide the switch path that electrically connects the interconnection path 318A to the interconnection path 318B so that the interconnection path 318A, the switch path, and the interconnection path 318B provide a current path between the inductor terminal 312A and the inductor terminal 312B. It should be noted that in some embodiments the inductor terminal 312A is at one end of the inductor 308 while the inductor terminal 312B is at another end of the inductor 308. However, the inductor terminal 312A may also be a conductive pad that is electrically connected through a trace or the like to one end of the inductor 308. Similarly, the inductor terminal 312B may be a conductive pad that is electrically connected through a trace or the like to another end of the inductor 308.

The active semiconductor devices 314 are configured to be turned on and turned off. When the active semiconductor devices 314 are turned on, the active semiconductor devices 314 are configured to close the current path for the current 313. The current 313 thus can propagate through the current path from the inductor terminal 312A to the inductor terminal 312B. As such, a capacitance of the capacitive structure 310A and a capacitance of the capacitive structure 310B are presented between the inductor terminals 312A, 312B. When the active semiconductor devices 314 are turned off, the active semiconductor devices 314 are configured to open the current path for the current 313. The current 313 cannot propagate from or to the inductor terminals 312A, 312B though the current path. Thus, the capacitance of the capacitive structure 310A and the capacitance of the capacitive structure 310B are not presented between the inductor terminals 312A, 312B, since the current path appears as an open circuit. In some implementations, there may be a finite parasitic capacitance between the inductor terminals 312A, 312B, even when the active semiconductor devices 314 are turned off.

To help maintain a high Q factor, the interconnection path 318A is vertically aligned so as to extend directly between the inductor terminal 312A and the device contact 316A. Similarly, the interconnection path 318B is vertically aligned so as to extend directly between the inductor terminal 312B and the device contact 316B. By vertically aligning the device contact 316A directly below the inductor terminal 312A and the device contact 316B directly below the inductor terminal 312B, the current 313 does not have to be routed back and forth vertically and horizontally in order to propagate from the inductor terminal 312A to the device contact 316A and from the device contact 316B to the inductor terminal 312B. This prevents additional losses and current crowding, since the current 313 does not have to go back and forth through metallic layers of different widths and thicknesses.

With regard to the interconnection path 318A, the inductor terminal 312A has an inductor terminal connection surface 320A that is attached to the interconnection path 318A, while the device contact 316A has a device contact connection surface 322A that is attached to the interconnection path 318A. The interconnection path 318A is formed to extend vertically such that the interconnection path 318A is substantially orthogonal to both the inductor terminal connection surface 320A and the device contact connection surface 322A. The interconnection path 318A extends directly between the inductor terminal 312A and the device contact 316A such that the current 313 has a direction D1 of current flow through the interconnection path 318A that is substantially orthogonal to a direction D2 of current flow of the current 313 through the inductor terminal 312A. As shown in FIG. 37, the entire interconnection path 318A is aligned directly between the inductor terminal connection surface 320A and the device contact connection surface 322A. Furthermore, the interconnection path 318A extends directly between the inductor terminal 312A and the device contact 316A such that the direction D1 of current flow through the interconnection path 318A is also substantially orthogonal to a direction D3 of current flow of the current 313 through the active semiconductor devices 314.

With regard to the interconnection path 318B, the inductor terminal 312B has an inductor terminal connection surface 320B that is attached to the interconnection path 318B while the device contact 316B has a device contact connection surface 322B that is attached to the interconnection path 318B. The interconnection path 318B is formed to extend vertically such that the interconnection path 318B is substantially orthogonal to both the inductor terminal connection surface 320B and the device contact connection surface 322B. The interconnection path 318B extends directly between the inductor terminal 312B and device contact 316B such that the current 313 has a direction D4 of current flow through the interconnection path 318B that is substantially orthogonal to a direction D5 of current flow of the current 313 through the inductor terminal 312B. As shown in FIG. 37, the entire interconnection path 318B is aligned directly between the inductor terminal connection surface 320B and the device contact connection surface 322B. To minimize a length of the current path and thus also insertion losses, the interconnection path 318B extends directly between the inductor terminal 312B and the device contact 316B such that the direction D4 of current flow through the interconnection path 318B is also substantially orthogonal to the direction D3 of current flow of the current 313 through the active semiconductor devices 314. As shown in FIG. 37, the direction D4 through the interconnection path 318B is antipodal to the direction D2 through the interconnection path 318A. Furthermore, a first horizontal displacement between the inductor terminal 312A and the inductor terminal 312B is substantially equal to a second horizontal displacement between the device contact 316A and the device contact 316B.

In the embodiment shown in FIG. 37, the inductor 308 is formed by the package board 306. The package board 306 may have a package body 324 and metallic layers formed on or in the package body 324. The package body 324 may be formed by a plurality of board layers made from a non-conductive material. The non-conductive material may be a dielectric, a laminate, fibers, glass, ceramic, and/or the like. The dielectric may be a Silicon Oxide (SiOx), Silicon Nitride (SiNx), and/or the like. In this embodiment, the package board 306 is a laminate. The laminate may be FR-1, FR-2, FR-3, FR-4, FR-5, FR-6, CEM-1, CEM-2, CEM-3, CEM-4, CEM-5, CX-5, CX-10, CX-20, CX-30, CX-40, CX-50, CX-60, CX-70, CX-80, CX-90, CX-100, and/or the like. The metallic layers of the package board 306 may be used to form termini and passive impedance components (e.g., the inductor 308).

In this particular embodiment, the package board 306 is a laminate that defines a metallic layer 326 that is formed on a laminate surface 328. The metallic layer 326 is used to form the inductor terminals 312A, 312B of the inductor 308. The inductor 308 may be any type of suitable inductor. For example, the inductor 308 may be a folded inductor. Additionally, the inductor 308 may be a two-dimensional (2D) inductor or three-dimensional (3D) inductor. If the inductor 308 is the 2D inductor, the inductor 308 may be formed entirely from the metallic layer 326. On the other hand, if the inductor 308 is a 3D inductor, then multiple metallic layers provided by the package board 306 may be used to form the inductor 308. The current flow in the inductor 308 may be directed both horizontally and vertically, as in the case with 3D inductors, or just horizontally, as in the case of standard planar horizontal inductors. Additionally, the inductor 308 may be a vertical inductor. Thus, the current flow in the inductor 308 may also only be vertical.

As shown in FIG. 37, the semiconductor die 304 is attached to the package board 306. The semiconductor die 304 includes a semiconductor substrate 329 used to form active semiconductor components of the IC. More specifically, the active semiconductor devices 314 are formed by the semiconductor substrate 329. The semiconductor substrate 329 may be formed from doped and non-doped layers of a suitable semiconductor material. For example, the semiconductor material may be Silicon (Si), Silicon Germanium (SiGe), Gallium Arsenide (GaAs), Indium Phosphorus (InP), and/or the like. Typical dopants that may be utilized to dope the semiconductor layers are Gallium (Ga), Arsenic (As), Silicon (Si), Tellurium (Te), Zinc (Zn), Sulfur (S), Boron (B), Phosphorus (P), Aluminum Gallium Arsenide (AlGaAs), Indium Gallium Arsenide (InGaAs), and/or the like. Furthermore, metallic layers may be formed on a top, within, and/or on a bottom of the semiconductor substrate 329 to provide termini of the active semiconductor components, to form passive impedance elements, and/or the like. For example, a metallic layer is used to form the device contacts 316A, 316B of the active semiconductor devices 314. Insulating layers, such as oxide layers, and metallic layers may also be provided in or on the semiconductor substrate 329.

The semiconductor die 304 also includes a Back-End-of-Line (BEOL) 330 that is formed over the semiconductor substrate 329. The BEOL 330 may be formed from a non-conductive substrate and a plurality of metallic layers provided on or in the insulating substrate. As shown in FIG. 37, the interconnection path 318A that electrically connects the inductor terminal 312A to the device contact 316A is formed by the BEOL 330. Since the capacitive structure 310A is formed within the interconnection path 318A, the BEOL 330 also forms the capacitive structure 310A. Additionally, the interconnection path 318B that electrically connects the inductor terminal 312B to the device contact 316B is also formed by the BEOL 330. Since the capacitive structure 310B is formed within the interconnection path 318B, the BEOL 330 also forms the capacitive structure 310B.

The BEOL 330 includes a metallic layer M1, metallic layer M2, a metallic layer M3, and a metallic layer M4. Conductive vias are also provided in the BEOL 330 to couple the components on the semiconductor substrate 329 to one another. In this embodiment, the interconnection path 318A is formed by the metallic layers M1, M2, M3, and M4, and by conductive vias VA that interconnect the metallic layers M1, M2, M3, and M4 within the interconnection path 318A. Note that the metallic layer M1 is used to form a conductive pad in the interconnection path 318A that allows for external connections to the semiconductor die 304. This conductive pad is vertically aligned directly over the device contact 316A. In this embodiment, a connection pillar CPA electrically connects the inductor terminal 312A to the conductive pad formed by the metallic layer M1 in the interconnection path 318A. In fact, all of the metallic components in the interconnection path 318A are vertically aligned directly over the device contact 316A.

The interconnection path 318A has a path width PWA and the inductor terminal 312A has a line width LWA. To reduce and/or prevent current crowding within the interconnection path 318A, the path width PWA and the line width LWA are substantially equal. With regard to the capacitive structure 310A shown in FIG. 37, a top plate is formed from the metallic layer M2 and a bottom plate is formed from the metallic layer M3. The interconnection path 318A also includes a dielectric material DMA between the top plate and the bottom plate. The capacitive structure 310A is vertically aligned directly over the device contact 316A and directly underneath the inductor terminal 312A. Furthermore, the path width PWA of the interconnection path 318A is maintained substantially constant throughout the entire interconnection path 318A. As such, a top plate width of the top plate, a bottom plate width of the bottom plate, and the line width LWA are substantially equal. In this manner, the capacitive structure 310A is configured within the interconnection path 318A to prevent or reduce current crowding.

Also, in this embodiment, the interconnection path 318B is formed by the metallic layers M1, M2, M3, and M4, and by conductive vias VB that interconnect the metallic layers M1, M2, M3, and M4 within the interconnection path 318B. Note that the metallic layer M1 is used to form a conductive pad that is in the interconnection path 318B and allows for external connections to the semiconductor die 304. This conductive pad is vertically aligned directly over the device contact 316B. In this embodiment, a connection pillar CPB electrically connects the inductor terminal 312B to the conductive pad formed by the metallic layer M1 in the interconnection path 318B. In fact, all of the metallic components in the interconnection path 318B are vertically aligned directly over the device contact 316B. In alternative embodiments, the inductor 308 may formed by the BEOL 330. For example, the BEOL 330 may include several thick metallic layers. One or more of these thick metallic layers may be used to form the inductor 308. In this manner, the inductor 308 may be provided by the semiconductor die 304, while still providing a high Q factor.

The interconnection path 318B has a path width PWB and the inductor terminal 312B has a line width LWB. To reduce and/or prevent current crowding within the interconnection path 318B, the path width PWB and the line width LWB are substantially equal. With regard to the capacitive structure 310B shown in FIG. 37, a top plate is formed from the metallic layer M2 and a bottom plate is formed from the metallic layer M3. It should be noted that other metallic layers may be used to form the top plate and the bottom plate. The interconnection path 318B also includes a dielectric material DMB between the top plate and the bottom plate. The capacitive structure 310B is vertically aligned directly over the device contact 316B and directly underneath the inductor terminal 312B. Furthermore, the path width PWB of the interconnection path 318B is maintained substantially constant throughout the entire interconnection path 318B. As such, a top plate width of the top plate, a bottom plate width of the bottom plate, and the line width LWB are substantially equal. Accordingly, the capacitive structure 310B is configured within the interconnection path 318B to prevent or reduce current crowding and minimize the length of the current path. If an area of the capacitive structure 310A and an area of the capacitive structure 310B are each smaller than an area of the inductor terminal 312A and the inductor terminal 312B, respectively, the capacitive structures 310A, 310B may be split into smaller capacitive structures and distributed uniformly within the interconnection paths 318A, 318B. The same is true if the area of the capacitive structures 310A, 310B is smaller than an area of the interconnection paths 318A, 318B.

FIG. 38 illustrates another embodiment of the RF device 300 having the interconnection path 318A that electrically connects the inductor terminal 312A to device contact 316A, as described above in FIG. 37. However, in this embodiment, the number N is equal to one, and thus the RF device 300 shown in FIG. 38 just has the active semiconductor device 314A. Also, the interconnection path 318B (shown in FIG. 37) is not provided. Thus, the RF device 300 shown in FIG. 38 only includes the active semiconductor device 314A with the device contact 316A and the interconnection path 318A. Furthermore, a device contact 332A of the active semiconductor device 314A is grounded. For example, the active semiconductor device 314A may be grounded to a real ground or a virtual ground. Thus, the active semiconductor device 314A and the interconnection path 318A provide a current path between the inductor terminal 312A and ground. In this embodiment, the active semiconductor device 314A is a FET and the device contact 316A is a drain contact that is electrically connected to a drain DA of the active semiconductor device 314A. The device contact 332A is a source contact electrically connected to a source SA of the active semiconductor device 314A. (As shown in FIG. 37 multiple active semiconductor devices 314 may also form a stack of active semiconductor devices 314.)

The interconnection path 318A and the active semiconductor device 314A thus provide a current path for the current 313 from the inductor terminal 312A to ground. In this embodiment, the active semiconductor device 314A also includes a control contact 334A configured to receive a control voltage V_(CA). Since the active semiconductor device 314A is provided as the FET, the control contact 334A shown in FIG. 38 is a gate contact that electrically connects to a gate GA of the active semiconductor device 314A. The active semiconductor device 314A is configured to close the current path from the inductor terminal 312A to ground in response to the control voltage V_(CA) being provided in an activation voltage state. In this case, the current 313 propagates from the inductor terminal 312A provided by the package board 306 through the interconnection path 318A and the active semiconductor device 314A to ground. As such, the capacitance of the capacitive structure 310A is presented at the inductor terminal 312A when the active semiconductor device 314A is turned on. The active semiconductor device 314A is configured to open the current path from the inductor terminal 312A to ground in response to the control voltage V_(CA) being provided in a deactivation voltage state. Thus, the current 313 does not propagate to ground and the capacitance of the capacitive structure 310A is not presented at the inductor terminal 312A when the active semiconductor device 314A is turned off. In some embodiments, parasitic capacitances may provide a parasitic current path.

Since the interconnection path 318A is vertically aligned so as to extend directly between the inductor terminal 312A and the device contact 316A, a length of the interconnection path 318A is minimized. Thus, parasitic impedances presented by the interconnection path 318A are minimized. For instance, a parasitic inductance and a parasitic resistance of the interconnection path 318A are minimized. Note that in this embodiment, a solder ball SBA electrically connects the interconnection path 318A to the inductor terminal 312A, rather than the conductive pillar CPA shown in FIG. 37. The current path may have a close contour with a certain path length.

FIG. 39 illustrates another embodiment of the IC package 302 with an embodiment of an RF device 300(1) and an embodiment of an RF device 300(2) integrated into the IC package 302. Both the RF device 300(1) and the RF device 300(2) are similar to the RF device 300 shown in FIG. 37, except that the integer number N for both the RF device 300(1) and the RF device 300(2) is equal to one (1). As shown in FIG. 39, the RF device 300(1) includes a capacitive structure 310A(1), a capacitive structure 310B(1), an inductor terminal 312A(1), an inductor terminal 312B(1), an active semiconductor device 314A(1) that includes a device contact 316A(1) and a device contact 332A(1), an interconnection path 318A(1), and an interconnection path 318B(1). The capacitive structure 310A(1), the capacitive structure 310B(1), the inductor terminal 312A(1), the inductor terminal 312B(1), the active semiconductor device 314A(1), the interconnection path 318A(1), and the interconnection path 318B(1) are the same as the capacitive structure 310A, the capacitive structure 310B, the inductor terminal 312A, the inductor terminal 312B, the active semiconductor device 314A, the interconnection path 318A, and the interconnection path 318B shown in FIG. 37. However, since the integer number N for the RF device 300(1) is equal to one (1), the interconnection path 318B(1) electrically connects the inductor terminal 312B(1) to the device contact 332A(1) of the active semiconductor device 314A(1).

With regard to the RF device 300(2), the RF device 300(2) includes a capacitive structure 310A(2), a capacitive structure 310B(2), an inductor terminal 312A(2), an inductor terminal 312B(2), an active semiconductor device 314A(2) that includes a device contact 316A(2) and a device contact 332A(2), an interconnection path 318A(2), and an interconnection path 318B(2). The capacitive structure 310A(2), the capacitive structure 310B(2), the inductor terminal 312A(2), the inductor terminal 312B(2), the active semiconductor device 314A(2), the interconnection path 318A(2), and the interconnection path 318B(2) are the same as the capacitive structure 310A, the capacitive structure 310B, the inductor terminal 312A, the inductor terminal 312B, the active semiconductor device 314A, the interconnection path 318A, and the interconnection path 318B shown in FIG. 37. However, since the integer number N for the RF device 300(2) is equal to one (1), the interconnection path 318B(2) electrically connects the inductor terminal 312B(2) to the device contact 332A(2) of the active semiconductor device 314A(2).

As shown in FIG. 39, the inductor terminal 312B(1) of the RF device 300(1) is electrically connected to the inductor terminal 312A(1) through a trace 336 provided by the package board 306. As shown in FIG. 39, a configuration of the RF devices 300(1) and 300(2) allows for connections between the RF device 300(1) and the RF device 300(2) using thicker metallic layers, such as the metallic layer that forms the trace 336 and the inductor terminals 312A(1), 312A(2), 312B(1), and 312B(2). The metallic layers M2, M3, and M4 within the BEOL 330 may be thin in comparison to the metallic layer M1 at a surface of the BEOL 330 and the metallic layers in the package board 306. Thus, the configuration of the RF devices 300(1), 300(2) routes the current vertically through the interconnection paths 318A(1), 318B(1), 318A(2), 318B(2) to and from the active semiconductor devices 314A(1), 314A(2). In order to route the current 313 between the RF devices 300(1), 300(2), the trace 336 is horizontally oriented. However, since the trace 336 is relatively thick, current crowding is reduced or prevented, and thus a Q factor of the RF devices 300(1), 300(2) is not degraded. In alternative embodiments, the trace 336 may be realized by a thick metal layer in the BEOL 330.

FIG. 40 illustrates another embodiment of the IC package 302 with another embodiment of an RF device 300(1) and another embodiment of the RF device 300(2) integrated into the IC package 302. In the embodiment of the RF device 300(1) shown in FIG. 40, the interconnection path 318A(1) electrically connects the inductor terminal 312A(1) to the device contact 316A(1) of the active semiconductor device 314A(1). The capacitive structure 310A(1) is formed in the interconnection path 318A(1) within the BEOL 330. Similarly, with regard to the embodiment of the RF device 300(2) shown in FIG. 40, the interconnection path 318A(2) electrically connects the inductor terminal 312A(2) to the device contact 316A(2) of the active semiconductor device 314A(2). The capacitive structure 310A(2) is formed in the interconnection path 318A(2) within the BEOL 330. However, in this embodiment, the RF device 300(1) and the RF device 300(2) are interconnected using a trace 338 formed from the metallic layer M4 within the BEOL 330. Although the metallic layer M4 is relatively thin, the trace 338 may be provided with the metallic layer M1 when the RF device 300(1) and the RF device 300(2) are relatively close. If a distance between the RF devices 300(1), 300(2) is moderate, multiple metallic layers (thin and/or thick) can be stacked to reduce current path losses.

FIG. 41 illustrates an embodiment of the capacitive structure 310, which may be provided as an embodiment of any of the capacitive structures 310A, 310B, 310A(1), 310A(2), 310B(1), or 310B(2) shown in FIGS. 37-40. The capacitive structure 310 is a metal-insulator-metal capacitive structure formed within an interconnection path 318, which may be provided as an embodiment of any of the interconnection paths 318A, 318B, 318A(1), 318A(2), 318B(1), or 318B(2) shown in FIGS. 37-40. A top plate 340 of the capacitive structure 310 is formed by the metallic layer M2 of the BEOL 330, while a bottom plate 342 is formed by the metallic layer M3 of the BEOL 330. A dielectric layer DM is formed between the top plate 340 and the bottom plate 342 in the capacitive structure 310. Since the metallic layer M2 and the metallic layer M3 are relatively thin, horizontal current flow would cause current crowding and result in Q factor degradation. Thus, the capacitive structure 310 provides a MIM configuration in which the current 313 flows vertically through the capacitive structure 310. To prevent current circulation, an array of conductive vias 344 is formed on a bottom surface of the bottom plate 342 to split the current 313. In this manner, the current 313 propagates through the interconnection path 318 to or from the semiconductor substrate 329 (shown in FIG. 37). With the MIM capacitive structure, the current 313 propagates vertically in the metal and isolation material (change in polarization).

FIG. 42 illustrates another embodiment of the capacitive structure 310, which may be provided as an embodiment of any of the capacitive structures 310A, 310B, 310A(1), 310A(2), 310B(1), and 310B(2), shown in FIGS. 37-40. The capacitive structure 310 is a metal-oxide-metal (MOM) capacitive structure formed within an interconnection path 318, which may be provided as an embodiment of any of the interconnection paths 318A, 318B, 318A(1), 318A(2), 318B(1), or 318B(2) shown in FIGS. 37-40. The MOM capacitive structure shown in FIG. 42 has a vertical configuration so that the current 313 flows vertically through metallic components in the MOM capacitive structure. In this regard, the capacitive structure 310 shown in FIG. 42 includes a top plate 346 formed by the metallic layer M1 of the BEOL 330. The metallic layer M1 is exposed externally while a bottom plate 348 is formed by the metallic layer M3 of the BEOL 330. The capacitive structure 310 includes an array of traces 350 between the top plate 346 and the bottom plate 348. The array of traces 350 is provided by the metallic layer M2 within the BEOL 330. The traces in the array of traces 350 are electrically connected to the top plate 346 and the bottom plate 348 by conductive vias CVC. In this manner, the current 313 is divided when flowing through the conductive vias CVC and the array of traces 350.

An oxide layer OM is formed between the top plate 346, the bottom plate 348, and the array of traces 350 in the capacitive structure 310. Since the array of traces 350 is formed by the metallic layer M2, the traces 350 are substantially parallel to one another. Accordingly, the current flow of the current 313 is horizontal with respect to the oxide layer OM. In the oxide layer OM, there is no carrier conductor; rather, there is a polarization change. Since the current 313 propagates vertically through the top plate 346, the conductive vias CVC, the array of traces 350, and the bottom plate 348, current crowding is avoided. While the current flow is horizontal through the oxide layer OM, this does not cause significant current crowding and does not significantly degrade a Q factor of the capacitive structure 310.

FIG. 43 illustrates a top view of another embodiment of a capacitive structure 310(1), which may be provided as an embodiment of any of the capacitive structures 310A, 310B, 310A(1), 310A(2), 310B(1), and 310B(2), shown in FIGS. 37-40; a capacitive structure 310(2); and a capacitive structure 310(3). Each of the capacitive structures 310(1), 310(2), 310(3) is a metal-to-metal (MTM) capacitive structure formed within an interconnection path 318, which may be provided as an embodiment of any of the interconnection paths 318A, 318B, 318A(1), 318A(2), 318B(1), or 318B(2) shown in FIGS. 37-40. Thus, in this embodiment, the interconnection path 318 includes the multiple capacitive structures 310(1), 310(2), 310(3). The MTM capacitive structures 310(1), 310(2), 310(3) can be formed using very few metallic layers, potentially resulting in low costs and a shorter interconnection path 318.

In this embodiment, the interconnection path 318 is electrically connected and formed directly over active semiconductor devices 314(1), 314(2), and 314(3), which in this embodiment are FETs. More specifically, the interconnection path 318 is electrically connected to drain contacts D of each of the active semiconductor devices 314(1), 314(2), and 314(3). The active semiconductor devices 314(1), 314(2), and 314(3) also include gate contacts G and the source contacts S. The drain contacts D and the source contacts S are formed as interleaved metallic fingers. It should be noted that the MTM capacitive structure can be implemented on one or more of the device contacts D, S, G of each of the active semiconductor devices 314(1), 314(2), and 314(3).

Each of the capacitive structures 310(1), 310(2), 310(3) shown in FIG. 43 is formed using parallel metallic walls formed across the drains D of the active semiconductor devices 314(1), 314(2), and 314(3). Alternating metallic walls of the capacitive structure 310(1) are electrically connected to the drain D of the active semiconductor device 314(1) while the other metallic walls are electrically connected to a metallic layer (not shown) in the interconnection path 318 above the capacitive structure 310(1). As a length of each of the metallic walls is increased, the capacitance of the capacitive structure 310(1) is increased. With regard to the capacitive structure 310(2), alternating metallic walls of the capacitive structure 310(2) are electrically connected to the drain D of the active semiconductor device 314(2) while the other metallic walls are electrically connected to a metallic layer (not shown) in the interconnection path 318 above the capacitive structure 310(2). As each of a length of each of the metallic walls is increased, the capacitance of the capacitive structure 310(2) is increased. Finally, alternating metallic walls of the capacitive structure 310(3) are electrically connected to the drain D of the active semiconductor device 314(3) while the other metallic walls are electrically connected to a metallic layer (not shown) in the interconnection path 318 above the capacitive structure 310(3). As each of a length of each of the metallic walls is increased, the capacitance of the capacitive structure 310(3) is increased. In this embodiment, each of the active semiconductor devices 314(1), 314(2), and 314(3) is configured to be turned on and off independently. As such, the capacitive structures 310(1), 310(2), 310(3) can provide an overall digitally programmable capacitive structure, such as a digital array of capacitors. The MTM capacitive structure can also be realized using directly active or passive device interconnect metal layers requiring no extra metal layers or fewer metal layers.

FIG. 44 illustrates a top view of another embodiment of the capacitive structures 310(1), 310(2), and 310(3). As in FIG. 43, each of the capacitive structures 310(1), 310(2), 310(3) in FIG. 44 is an MTM capacitive structure formed within the interconnection path 318. In the embodiment shown in FIG. 44, the interconnection path 318 is electrically connected and formed directly over the same active semiconductor devices 314(1), 314(2), and 314(3) described above with respect to FIG. 43. However, instead of the parallel metallic walls, each of the capacitive structures 310(1), 310(2), 310(3) is formed using alternating posts encircled by metallic cages. The advantage of the capacitive structures 310(1), 310(2), 310(3) shown in FIG. 44 is that capacitances are realized in all directions and a capacitive density is determined by perimeters of the metallic cages.

FIG. 45 illustrates another embodiment of the capacitive structure 310(1). As in FIGS. 43 and 44, the capacitive structure 310(1) shown in FIG. 45 is an MTM capacitive structure. The capacitive structure 310(1) is formed using a metal interconnect. In this embodiment, the capacitive structure 310(1) is formed using parallel metallic walls formed across the drain contact D and the source contact S of the active semiconductor device 314(1). Alternating metallic walls of the capacitive structure 310(1) are electrically connected to the drain contact D of the active semiconductor device 314(1), while the other metallic walls are electrically connected to the source contact S of the active semiconductor device 314(1). This embodiment is particularly advantageous in silicon-on-insulator (S01)-type processes and silicon-oxide-silicon (SOS)-type processes because drain-to-source diffusions are small. Furthermore, parasitic capacitances to the gate contact G of the active semiconductor device 314(1) are less critical. As such, diffusions can be increased significantly without significantly degrading a Q factor of the capacitive structure 310(1). If one side of the active semiconductor device 314(1) is grounded, only the diffusion on that side may be increased. This provides an example of an asymmetric capacitive structure.

FIG. 46 illustrates yet another embodiment of the capacitive structure 310(1). As in FIGS. 43-45, the capacitive structure 310(1) shown in FIG. 46 is an MTM capacitive structure. The capacitive structure 310(1) is formed using a metal interconnect. The capacitive structure 310(1) shown in FIG. 46 is similar to the embodiment of the capacitive structure 310(1) shown in FIG. 45. However, in this embodiment, the capacitive structure 310(1) is also built using parallel metallic walls connected to the gate contact G in addition to the parallel metallic walls electrically connected to the source contact S and the drain contact D of the active semiconductor device 314(1). This embodiment may be used with a planar semiconductor process, such as Complementary-Metal-Oxide Semiconductor (CMOS), Silicon Germanium (SiGe), Gallium Arsenide (GaAs), or Indium Phosphorus (InP)-type processes. The active semiconductor device 314(1) is a FET. However, in alternative embodiments, the active semiconductor device 314(1) may be a bipolar junction transistor (BJT), a heterojunction bipolar transistor (HBT) diode, or the like.

Those skilled in the art will recognize improvements and modifications to the preferred embodiments of the present disclosure. All such improvements and modifications are considered within the scope of the concepts disclosed herein and the claims that follow. 

What is claimed is:
 1. A radio frequency (RF) device, comprising: an inductor having a first inductor terminal; and a semiconductor die comprising: one or more active semiconductor devices that include a first device contact, wherein the first device contact is vertically aligned so as to be positioned directly below the first inductor terminal; a first interconnection path that electrically connects the first inductor terminal to the first device contact, wherein the first interconnection path is vertically aligned so as to extend directly between the first inductor terminal and the first device contact; and a first capacitive structure that is formed within the first interconnection path.
 2. The RF device of claim 1, wherein the semiconductor die comprises a semiconductor substrate and a Back End of Line (BEOL) formed over the semiconductor substrate, wherein: the one or more active semiconductor devices are formed by the semiconductor substrate; and the first capacitive structure is formed by the BEOL.
 3. The RF device of claim 1, wherein the semiconductor die comprises a semiconductor substrate and a Back End of Line (BEOL) formed over the semiconductor substrate, wherein: the one or more active semiconductor devices are formed by the semiconductor substrate; and the first interconnection path is formed by the BEOL.
 4. The RF device of claim 1 further comprising a package board wherein: the inductor is formed by the package board; and the semiconductor die is attached to the package board.
 5. The RF device of claim 4, wherein the package board comprises a laminate having a laminate surface and a metallic layer formed on the laminate surface, wherein the metallic layer forms the first inductor terminal.
 6. The RF device of claim 5 wherein the metallic layer forms all of the inductor.
 7. The RF device of claim 1 wherein: the inductor further comprises a second inductor terminal; the one or more active semiconductor devices further includes a second device contact, the second device contact being vertically aligned so as to be positioned directly below the second inductor terminal; and the semiconductor die further comprises a second interconnection path and a second capacitive structure, wherein: the second interconnection path electrically connects the second inductor terminal to the second device contact, the second interconnection path being vertically aligned so as to extend directly between the second inductor terminal and the second device contact; and the second capacitive structure is formed in the second interconnection path.
 8. The RF device of claim 7 wherein the one or more active semiconductor devices electrically connect the first device contact to the second device contact.
 9. The RF device of claim 7 wherein the one or more active semiconductor devices provide a switch path that electrically connects the first interconnection path to the second interconnection path so that the first interconnection path, the switch path, and the second interconnection path provide a current path between the first inductor terminal and the second inductor terminal.
 10. The RF device of claim 9 wherein the one or more active semiconductor devices are configured to: open the current path when the one or more active semiconductor devices are turned on; and close the current path when the one or more active semiconductor devices are turned off.
 11. The RF device of claim 7 wherein the semiconductor die comprises a semiconductor substrate and a Back End of Line (BEOL) formed over the semiconductor substrate, wherein: the one or more active semiconductor devices are formed by the semiconductor substrate; the first interconnection path is formed by the BEOL; and the second interconnection path is formed by the BEOL.
 12. The RF device of claim 7 wherein a first horizontal displacement between the first inductor terminal and the second inductor terminal is substantially equal to a second horizontal displacement between the first device contact and the second device contact.
 13. The RF device of claim 12 wherein the one or more active semiconductor devices are positioned horizontally directly between the first interconnection path and the second interconnection path.
 14. The RF device of claim 1 wherein: the first interconnection path has a path width; and the first inductor terminal has a terminal width; wherein the path width and the terminal width are substantially equal.
 15. The RF device of claim 1 wherein: the first inductor terminal has a first inductor terminal connection surface that is attached to the first interconnection path; the first device contact has a first device contact connection surface; and the first interconnection path is formed to extend vertically such that the first interconnection path is substantially orthogonal to both the first inductor terminal connection surface and the first device contact connection surface.
 16. The RF device of claim 15 wherein all of the first interconnection path is aligned directly between the first inductor terminal connection surface and the first device contact connection surface.
 17. The RF device of claim 1 wherein: the first inductor terminal has a first inductor terminal connection surface that is attached to the first interconnection path; the first device contact has a first device contact connection surface; and the first interconnection path is formed to extend vertically such that the first interconnection path is aligned directly between the first inductor terminal connection surface and the first device contact connection surface.
 18. The RF device of claim 1 wherein the first interconnection path extends directly between the first inductor terminal and the first device contact such that a current has a first direction of current flow through the first interconnection path that is substantially orthogonal to a second direction of current flow of the current through the first inductor terminal.
 19. The RF device of claim 18 wherein the first interconnection path extends directly between the first inductor terminal and the first device contact such that the first direction of current flow through the first interconnection path is also substantially orthogonal to a third direction of current flow of the current through the one or more active semiconductor devices.
 20. The RF device of claim 1 wherein the first capacitive structure has an array of traces configured to split a current propagating within the first interconnection path.
 21. The RF device of claim 1 wherein the inductor is selected from a group consisting of a horizontal inductor, a vertical inductor, and a three-dimensional inductor.
 22. The RF device of claim 1 wherein the first capacitive structure comprises a top plate and a bottom plate and wherein: the first inductor terminal has a terminal width; the top plate has a top plate width; and the bottom plate has a bottom plate width; and wherein the terminal width, the top plate width, and the bottom plate width are substantially equal.
 23. The RF device of claim 1 wherein the first capacitive structure is a metal-insulator-metal (MIM) capacitive structure.
 24. The RF device of claim 1 wherein the first capacitive structure is a metal-oxide-metal (MOM) capacitive structure.
 25. The RF device of claim 1 wherein the first capacitive structure is a metal-to-metal (MTM) capacitive structure.
 26. The RF device of claim 25 wherein the MTM capacitive structure comprises parallel metallic walls formed across the first device contact.
 27. The RF device of claim 25 wherein the MTM capacitive structure comprises alternating metallic posts encircled by metallic cages.
 28. The RF device of claim 1 wherein the one or more active semiconductor devices consist of a field effect transistor.
 29. The RF device of claim 1 wherein the one or more active semiconductor devices comprise a stack of field effect transistors.
 30. An integrated circuit (IC) package comprising: a package board; an inductor formed by the package board, wherein the inductor has a first inductor terminal; and a semiconductor die comprising a semiconductor substrate and a Back-End-of-Line (BEOL) formed over the semiconductor substrate, wherein: the semiconductor substrate comprises one or more active semiconductor devices that include a first device contact, wherein the first device contact is vertically aligned so as to be positioned directly below the first inductor terminal; and the BEOL comprises: a first interconnection path that electrically connects the first inductor terminal to the first device contact, wherein the first interconnection path is vertically aligned so as to extend directly between the first inductor terminal and the first device contact; and a first capacitive structure that is formed within the interconnection path. 